NORTHWESTERN
UNIVERSITY
LIBRARY
EVANSTON, ILLINOIS
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\
-/
FIRST ANNUAL PUBLICATION.
COLORADO COLLEGE STODIES.
Papers read before the Colorado College
Scientific Society.
CQLORADO SPRINGS, COLO.,
1890.
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FIRST ANNUAL PUBLICATION.
Papers read before the Colorado College
Scientific Society.
COLORADO SPRINGS, COLO.,
1890.
C'll^
d
V l-'O
REGISTER PUBLISHING COMPANY, ANN ARBOR, MICHIGAN.
OFFICERS, 1890-1891.
President, .... Peofessor Frank H. Loud.
Vice-Presidents, Professors William Strieby and Eloise Wickard.
Secretary, .... Professor Florian Cajori.
Treasurer, ..... Mr. O. H. Richardson.
PLACE OF MEETING.
PALMER HALL, COLORADO COLLEGE.
TABLE OF CONTENTS.
faqei
Announcement 5
A Rigorous Elementary Proof of the Binomial Theorem. F. H.
Loud 7
On Certain Cubic Curves. F. H. Loud 16
A Study of the Inductive Theories of Bacon, Whewell, and Mill.
Benj. Ives Gillman 17
A Mathematical Text-book of the Last Century. F. Cajori 27
Horace, Od. III. 1. 34. George L. Hendrickson 34
Quinti Ciceronis Commentariolum Petitionis XI, § 43. (B. et K.
vol. IX, p. 487.) George L. Hendrickson 36
ANNOUNCEMENT.
The Colorado College Scientific Society was organized on the
22nd of January, 1890. The five regular meetings, thus far
held, have shown on the part of its members a gratifying zeal
for the welfare of the Society, and earnest interest in science.
Though only five months old, the Society ventures to send forth
a small volume containing six of the papers read at its meet¬
ings; and requests of associations of like nature the favor of an
exchange of publications, hoping that subsequent volumes will,
more fully than the present pamphlet, substantiate a claim to
attention.
Among the papers read before the Society there were others
not inferior to those included in this publication, in point of
originality or of interest of topic or treatment. For one reason
or another, it has not been practicable to present them here.
The following is a complete list of the papers and " reports "
read before the Society:
February 11, '90.
A Rigorous Elementary Proof of the Binomial Theorem.
F. H. Loud.
The American School of Archaeology at Athens. W. D.
Sheldon.
Herr Tarchenofif's Experiments upon the Effect of Mental
Stimulation on Electric Currents in the Human Skin.
F. Cajori.
March 10, '90.
Socialism. O. H. Richardson.
On Certain Cubic Curves. F. H. Loud.
Lanciani's Ancient Rome in the Light of Recent Excava¬
tions. G. L. Hendrickson.
6
Colorado College Studies.
April 15, '90.
Theories of Inductive Inference. Benj. Ives Gilman.
A Mathematical Text-book of the Last Century. F. Cajori.
The Geologic Features of Eifle Creek Valley. W. L.
Wilder.
May 13, '90.
On the Method of Lighting Greek Temples. W. D.
Sheldon.
Horace, Od. Ill, 1, 84. G. L. Hendrickson.
Quinti Ciceronis Commentariolum Petitionis XI, § 43, (B.
et K., Vol. IX, p. 487). G. L. Hendrickson.
June 10, '90.
The Single Tax Theory of Henry George. J. D. Dillen-
back.
A RIGOROUS ELEMENTARY PROOF OF THE BINO¬
MIAL THEOREM.
BY FRANK H. LOUD.
The text-books of Algebra in general use in the colleges of
this country employ, as a means of treating some of the subjects
presented, a few well-known infinite series, of which the most
necessary are the binomial formula, the logarithmic and the
exponential series. Taylor's or McLaurin's theorem, or both,
are often added, or sometimes made the basis of the proof given
for the others. Or the binomial formula may be used as the
fundamental theorem, and from it may be deduced by rigorous
proofs whatever series are required in the treatment of logar¬
ithms or of higher equations, in so far as these subjects are
usually discussed in elementary works. A chapter on the theory
of infinite series necessarily accompanies the foregoing, in which
the student is made acquainted with the idea of convergence,
and furnished with the more simple tests, by which the conver¬
gence of series may in many cases be proved.
But the discussion of infinite series in these text-books is
not only elementary (as a matter of course), but also to such a
degree incomplete, that in almost every case it fails to warrant
the use made in the text-book itself of the series employed; so
that it is not too inuch to say that all our text-books, except a
very few which are so difficult as to be seldom used, offer inac¬
curate proofs of the fundamental theorems above mentioned,
thus offering to the student in lieu of a demonstration an argu¬
ment that is part fallacious.*
•To the general prevalence of this defect in our college Algebras, the attention of the
writer was called by Prof. F. Cajori, to whose suggestions and criticisms, in aid of the
present attempt to suppiy that defect, a debt is due which it is a pleasure to acknowl -
edge.
8
Colorado College Studies.
The form which the fallacy usually takes is the assumption
that when two infinite series are multiplied together, if the
factor series are both convergent, the product series will also
converge, and that to a sum which is the product of the
sums of the factor series. This proposition is not only
unproved but false; but though it is not explicitly stated, the
student is led to assume it, which of course he does without
hesitation.
The distinction here required is that between merely con-,
vergent and (so-called) absolutely convergent series, under¬
standing by the latter such a series as remains convergent
when all of its negative terms are made positive without
change of numerical value, so that in the transformed series
all the terms are of like sign. Abel furnished a rigorous
proof of the binomial formula, by establishing that when
two absolutely convergent series are multiplied the product
is a convergent series;'and that whenever the multiplication
of two convergent series yields a convergent result, the sum
which the product-series approaches is the product of the
sums approached by the factor-series. But Abel's proof has
generally been regarded as too abstruse for an elementary
work.
The development of {x y)'^ when n is of the form — m
± P)
or (m, p, and q being positive integers), may be obtained
2
by the following method, which is believed to be both rigorous
and elementary, and involves the demonstration of a theorem
which forms a special case only of that of Abel. I assume that
the case in which n is a positive integer has been proved by
either of the usual rigorous methods (e. g., that of induction),
and that the ordinary definitions and theorems concerning con¬
vergence have been given. From one of these, viz.; that " a
series whose successive terms diminish indefinitely is conver¬
gent," (and I would add, absolutely convergent) "when the
ratio of the m th term to the term preceding, as m is indefin¬
itely increased, approaches a constant value which is numer-
Proof of Binomial Theorem.
9
ically less than unity," may be deduced the conclusion that a
series in the form
n n n—1 n n—\ n—2,
1 + — a? H . x' H . . +
1 12 12 3
is absolutely convergent without regard to the value of n, pro¬
vided X has a value numerically less than one.
•I require to establish the following definitions and the¬
orems :
Definition—"By the product of two series (whether finite or
convergent or divergent), is meant a new series formed by mul¬
tiplying the several terms of the one series by those of the
other, and grouping the partial products as in the example
below; viz.: so that any term (the rrath) of the product-series
consists of the sum of m partial products (monomials), being
all of those partial products wherein the sum of the term-num¬
bers of the two factors is m -|- 1. (By "term-number " I mean
the number of the term formed by the factor in question in the
series from which it is taken. Thus the third term of the mul¬
tiplier has the term-number 3, and the second term of the mul¬
tiplier has 2, and the product of these two factors, as the sum of
the term-numbers is 5, will form a part of the 4th term of the
product. In the example the term-numbers appear as sub¬
scripts). For example, multiply
+ <^2 +03 + <^3 +
by &i + \ + ^>3 + +
O161 -|- afil + 0361 -|- afii
+ + ®2^2 "b ®3^2 "b .•
+ O-fis "b ®2^3 "b
+ +
1st, 2d, 3d, 4th, term of the product.
As a second example, the first four terms of the product of
the series ft-bfe + c-bd+ bym-bTC-bp + 9+
are {am) -b {ctn + hm) + (op + hn + cm) + (og + &p+
cn + dm).
Theorem. If the product of two absolutely convergent series
10
Colorado College Studies.
be convergent, the sum which it approaches is the product of
the sums approached by the two series which are its factors.
Consider first the case in which all the terms of both series
are positive. If we denote by r some definite number, and sup¬
pose each factor-series extended to and indefinitely beyond the
rth term, the first r terms in the product will contain all the
partial products in which the sum of the term-numbers does not
exceed r -j- 1. The aggregate of these partial products we will
denote by A. The complete product of the first r terms of the
first series by the first r terms of the second contains, in addi¬
tion to the foregoing, those partial products in which, although
the sum of the two term-numbers exceeds r -\- 1, yet neither of
them separately exceeds r. The aggregate of these additional
partial products we will call B. And finally, the complete pro¬
duct of the two series contains in addition to both A and B,
those partial products (the limit of whose sum we will call C)
in which the term-number of either factor exceeds r. Now let
us suppose the number r to be increased. Since the product is
a convergent series, the sum A of the first r terms approaches
the whole sum of the series. Hence B C approaches zero.
But since both B and O consist of positive terms only, if
B -j- C approaches zero, B and C must each approach zero as r
is increased. Hence the sum A -f- B approaches the same sum
as A. But A -f- B contains the entire product of the first r
terms of the two series, and as r is increased the sum of the
first r terms approaches in each series the sum of that series.
Hence the sum which the product-series approaches is identi¬
cal with the product of the sums of the separate series.
Next, if either series or both contains negative terms, some
of the partial products will be negative, but if B approaches
zero when all the partial products which compose it are posi¬
tive, it will certainly do so when some of them are negative, for
the sum of a number of quantities of two opposite signs must
always be nearer zero than the sum of the positive values of
the same quantities. Therefore, as before, the sum which A
and B approaches is the same as that which A approaches, and
the same conclusion follows as in the previous case.
Proof of Binomial Theorem.
11
Corollary. If, instead of absolutely convergent series, any
of the three series mentioned in the foregoing theorem, as fac¬
tors or product, should consist of a finite number of terms, the
theorem will still apply, for a finite series may be regarded as a
convergent one in which all the terms beyond a certain number
vanish.
Theorem. In an equation containing several literal quanti¬
ties, when each member is reducible to a finite number of
rational terms, if the equation be true for an unlimited number
of values for each literal quantity, while the selection of partic¬
ular values for one or more of the latter does not affect the pos¬
sible values assignable to the others, the numbers of the equa¬
tion must be identically equal.*
For when we have chosen particular values of all the letters
but one, the equation, if it were not an identity, would deter¬
mine the value of the remaining letter, so that it could not have
an indefinite number of values. By selecting successively sev¬
eral different sets of values for all but one of the letters we may
obtain as many different equations as we please for the remain¬
ing letter, say as many as there are different powers of that let¬
ter in the equation, and this group of equations must by the
terms of the hypothesis be satisfied by any one of an indefinite
number of values of that letter, whereas if the original equa¬
tion were not identical, such a group of equations would de¬
termine linearly each power of the quantity to a single value.
Definition. By "a series in the form
n u n—1
1 -I- — x -I- —. -1- ...
I 1 2
is meant any series derived from this by assigning to n some
particular value, whether positive or negative, integral or frac¬
tional.
Theorem. If two series, each in the form
II n n—1
1 H a? H • +
* Note that the hypothesis is not that each quantity may take any value whatever,
(which would make the theorem tautological) but that it may take any one of an
indefinite number of values.
12 CoLOEADO College Studies.
and having as values of n the numbers s and /, be multiplied
together, the product will be a series in the form
n n 71—1
1 _| X -\ . + ,
1 1 2
having for the value of n the number s t
The actual multiplication, through the first few terms, may
be written out as follows:
s s s—1 s s—1 s—2
1 _| X -{ . H . . ai" +....
I 12 12 3
t t t—1 t t—1 t—2
1 H X . x' H . . a? +—
1 12 12 3
s s s—1 s s—1 s—2
1 H X . x^ -\ . . a:® +
1 12 12 3
t s t s s—1 t
— X -\ . — x' H . . — a:® +
1 11 12 1
t t—1 s t t—1
—. a;® H . —. X? +
12 112
t t-\ t—2
—. . +
1 2 3
Here it is obvious that that which must be shown, in order
to prove the theorem, is that the coefficients of the successive
powers of x, found by adding the above columns, are identical
with the coefficients of corresponding powers in the series
S t S "f- t s t — 1
1 H X H . a;® +....
1 1 2
It is apparent that 1 is identical with 1, and
s t 5 + i
1 with ;
1 1 1
and it may be proved by trial, (with successively greater diffi¬
culty in the necessary reductions) that
s s—1 s t t t—1
l' 2 1' 1 1" 2
s + t s + i—1
is identical with . , etc., etc., as far as we please to
1 2
trouble, for any of these identities may be established by thi
application of the foregoing theorem. For they are known t(
hold true for an infinite number of values of s and t, viz., fo
all their positive integral values, since, the binomial theoren
having been proved for such values of the exponent, we kno\
that the factor-series are equal to (1 + £cand ( 1 + a;)' re
spectively, and the product-series to(l-f-£c)® + '. Hence th
coefficients of the first r powers of x in the product of the twi
series
s s s—1 t t t—1
1 H X . X* -f etc., and 1 H x -\ . x^ + etc.,
112 112
are identical with the coefficients of the like powers of x in thi
series
1 -|- X H . -f-
1 1 2
however great r may be.
Theorem.—The limit of the sum of the series
n n n—1
H x-\ . a? 4-
1 1 2
in which n is any negative integer and x is numerically les
than unity, is (1 + ar)".
For a series in this form, being multiplied by another serie
in the same form
m m in—1
1-1 33 H . x' 4- ,
1 1 2
in which m is any positive integer numerically greater than r
will yield as a product the series
m n m n m + n—1
1 4 X . x' +
1 1 2
which, since m 4- " is a positive integer, is a series of a finit
number of terms, and known to be equal to (1 4* x)"^ + No^
since in the given series
n n n—l
1 H .T -| . x^ etc.,
1 1 2
the value of x is numerically less than one, this series is absc
lutely convergent; but the series by which it is multiplied an
14
CoLOEADO College Studies.
the product-series are both finite. Hence the sum approached
by the given series, multiplied by the sum of the other factor-
series [which is (1 + a;)""] will be equal to the sum of the
product series, which is (1 + a:)'" + ". Therefore, the limit
required is (1 a?)™ + n ^ (1 + or (1 + «)".
Theorem.—The limit of the sum of the series
n n n—i
1-1 X -\ . +
1 1 2
p
in which n has any fractional value —, (when p and q are in-
tegers and q is positive), and in which x is numerically less than
_p
unity, is a value of the radical (l-|-a;)® or(l-|- a;)".
From the form of this series, and the fact that in it x is
numerically less than unity, it is known that the series is abso¬
lutely convergent. Let y represent its limit, and let the given
series be multiplied by itself. The resulting series is in the
form
n 11 11—\
Id 33-1 . a3'
1 1 2
2p
(?i having the value —) and, in consideration of the value of x
<1
is known to be absolutely convergent. Hence its sum ap¬
proaches the limit Let the operation of multiplying by the
given series be repeated until that series has been used q times
as a factor. It is proved as at the first multiplication that the
sum of each product-series approaches as a limit one of the suc¬
cessive powers of y, the last being y'i ; also that the last series
is in the form
n 11 n—1
1-1 X -\ . x^ ,
1 1 2
IP
where n has the value — or p. But by the previous theorem
I
the limit of this series is (1 + x)f. Hence 2/' = (l + a:)23or
P
y — (1 -f- a;) —, as was to be shown.
1
Peoof of Binomial Theokem.
15
It has now been shown that the limit of the series
n 11 n—1 11 n—1 n—2
1 h X . X' ^ . . X' + . . . .
1 12 12 3
is (1 + x)^ for all negative and fractional values of n, provided
X be numerically less than one. For values of x greater than
one, it is easy to show that the series is not convergent. In an
elementary treatise it is not necessary to consider the case aj = 1,
since the only result would be to establish certain expressions
for 0 " and 2 " no use for which need arise in such a work.
ON CERTAIN CUBIC CURVES.
BY F. H. LODD,
When a curve of the third order has three inflectional tan¬
gents which converge at a point, the curve belongs always to
that non-singular genus called simplex or unipartUe, and has
accordingly six more inflectional tangents, and these will also
converge by three to two other points. As only three of the
nine tangents are real, there will be two distinct cases, either
the three real tangents may converge, when there will be two
imaginary points, each the meeting-point of three imaginary
tangents, or two of the imaginary tangents may meet upon a
point of a real stationary tangent, and then each of the other
real inflectional tangents will have a point in which it is met by
two that are imaginary. The harmonic polars of three points of
inflection whose tangents converge, all pass through the point of
convergence of the three tangents. Through the same point,
pass also the two lines which join by threes the points of con¬
tact of the six remaining tangents.
When two of the points of convergence are imaginary, the
special case may arise that these two should be the circular
points at inflnity. The real inflectional tangents are then
asymptotes, and meet at equal angles, which are bisected by
the harmonic polars. The curve consists of three equal branches
lying alternately in three of the six angles formed by the asym¬
ptotes, and within each branch is a focus, the foci forming ver¬
tices of an equilateral triangle. In a system of tangential co¬
ordinates, wherein the coordinates of a line are its perpendicu¬
lar distances from these three foci, if we put the sum of these
coordinates ^ r) Z ~ 3<u, and write as the equation of the
circular points IJ = 0, then the equation of the curve is
81 (3?,: + .« IJ)' = 4TJ'.
4
A STUDY OF THE INDUCTIVE THEORIES OF BACON,
WHEWELL AND MILL.
BY BENJAMIN IVES OILMAN.
At the outset of modern scientific progress an investiga¬
tion into its correct method was undertaken by Francis Bacon.
Aristotle in his Metaphysics (XII, IV), says that we may justly
ascribe to Socrates the introduction into science of inductive or
adductive reasoning. Instances of this process, elsewhere given
by Aristotle, show that by this term he means the same argu¬
ment from particulars to a general which we now call Induction;
and in claiming for Socrates the invention of it, Aristotle draws
attention to what may be considered the main characteristic of
the Socratic method, the tendency to pierce through the vague
generalizations of common thought to the real content of knowl¬
edge beneath, to test general opinions by an appeal to the par¬
ticular facts on which they are based.
The dialectic of Socrates was an instrument of criticism em¬
bodying a rigid search for facts inconsistent with the opinion
under discussion (Hippias Major, etc.). A certain definition of
a general term being given, its insufficiency is shown by adduc¬
ing cases in which the term is used while the given character is
not present or in which the term is not used where it is present.
This feature of the Socratic dialectic, the criticism of generali¬
zations by adducing negative instances Lord Bacon alludes to
in the Novum Organum (I, CV), as the only previous example
of the use of his method. "We must analyze Nature," he
writes, " by pfoper rejections and exclusions, and then after a
sufficient number of negatives come to a conclusion on the
affirmative instances, which has not yet been done or even
attempted save only byT*lato, who does indeed employ this form
2
18
CoLOBADO College Studies.
of induction to a certain extent for the purpose of discussing
definition^ and ideas."
The fundamental distinction as well as the resemblance be¬
tween his method and that of Socrates are brought out by Lord
Bacon in this paragraph. The object of Socrates was the dis¬
cussion of definitions and ideas; that of Bacon the analysis of
Nature. Ideas were to the former the only real existences and
to him consequently the only true knowledge was to be obtained
by turning the mental gaze inward and clearing up the concep¬
tions in which they were involved. The particulars by which
he tested men's opinions were particular conceptions, the gen¬
eralizations which he reached were general ideas. Baconian
Induction, on the other hand, was an interrogation, not of Opin¬
ion but of Nature, and proceeded from particular facts of obser¬
vation to general truths concerning the Universe.
Common to both methods is their insistence upon a rigid
criticism of our conclusions: that of Plato being an appeal to
inconsistent conceptions, that of Bacon an appeal to incon¬
sistent facts.
"Man, the servant and interpreter of Nature:"—this, the
first clause of the Novum Organum, reflects the two funda¬
mental principles of Bacon's philosophy: the first that the final
end of knowledge is practice and that obedience to Nature is
the condition of success; the second that knowledge consists of
an Interpretation of Nature. In this phase emerges the main
characteristic of the Baconian method. Men were to cease
spinning sham knowledge from their own brains and to "dwell
purely and constantly among the facts of Nature;" (Preface to
Great Instauration) the tendency to rash generalization was to
be curbed; the Interrogation was to be substituted for the An¬
ticipation of Nature, the chief vice in Bacon's view, of former
philosophizing.
The induction which from the cases which we happen to have
observed flies at once to an assertion respecting all similar cases
"inductio per enumerationem simplicem," is in Bacon's mind
"res puerilis," (N. O. I, CV), and for it it was his aim to sub¬
stitute a method by which this natural tendency to generalize
The Inductive Theories.
19
should be controlled and fortified against error. According as
the problem of induction was looked at from its theoretical or
its practical side, it was stated by him on the one hand to be the
discovery of a Form, or necessary accompanying characteristic
of a class of phenomena; or, on the other, to be the " freeing of a
direction" (Val. Ter. C. 11), that is, the formation of a rule of
action (N. O., II, IV); but as he remarks, the two phrases des¬
cribe identically the same process viewed in different aspects.
The rules for the interpretation of Nature which were given by
Bacon (N. O. II, X), are in two divisions; first, those concern¬
ing the manner of forming general propositions from experi¬
ence; second, those regulating the derivation of new experiments
from these generalizations. The rules for the formation of gen¬
eral propositions are divided into three parts: (1) Rules for
observing. (2) For arranging our observations in reference to
the particular inquiry we are upon; and (3) Rules for true and
legitimate Induction. The method of such true Induction is
sketched in the XVIth axiom and consists of the exclusion from
the list of possible Forms of the phenomenon to be investiga¬
ted all qualities which are not found where the given phenome¬
non is, or are found when it is not, or are found to increase
when it diminishes or vice versa. "Then indeed," he contin¬
ues, "after the rejection and exclusion has been duly made,
there will remain at the bottom, all light opinions vanishing
into smoke, a Form affirmative, solid and true and well
defined."
In the light of further experience in Inductive investigation,
the theory of Induction thus laid down may be criticized as fol¬
lows: First: Bacon assumes that every nature or phenomenon
of a given kind has a Form or invariably accompanying quality;
and that the multifarious phenomena of the universe are the
result of the combination of such Forms, which are compara¬
tively few in number. This doctrine of Forms except, in so far
as it is allied to the idea of causation has not formed a part of
later theories of induction. Experience has not brought to
view any such invariability in the co-existences of phenomena;
and even as an approximation to a doctrine of causation, the
20
CoLOBADO College Studies.
probability of a plurality of Forms answering to a given
Nature, of more than one cause of a given effect, is therein
ignored.
With the exception of the test of similarity of variation the
method outlined presents the problem of Induction in a static
form in marked contrast to its modern dynamic aspect in con¬
nection with the ideas of causation, of progress and of evo¬
lution.
Second: The method claims a high degree of probability if
not an absolute certainty for a mechanical process of rejections
and exclusions, which in Bacon's words goes far to level men's
wits, since it proceeds by the surest rules and demonstrations
(N. O. I, CXXII).
That it should have seemed possible to Bacon to investigate
Nature by rule, to dispense with hypothesis and the scientific
imagination, the ay/tvoia or natural sagacity of Aristotle, evinces
a conception of the universe so different from that since preva¬
lent that we need not wonder that the Baconian method has
remained to this day an unused engine in the workshop where
he left it. We are constantly meeting in his works with expres¬
sions suggesting the limitations of the Universe; that its great
complexity, or subtlety in his phrase, is owing to the combina¬
tions of comparatively few elements.
Approximate completeness seemed therefore possible in the
natural and experimental histories which were to be the bases
of Induction; approximate completeness also in a knowledge of
the Forms to which we were to be led by that process. The
method was in Bacon's mind a chart and compass by which man
might soon explore the whole sphere of possible knowledge just
as the sailors of his time were touching the limits of the mate¬
rial globe.
" Be of good hope," he writes in the preface to the Great
Instauration, "nor imagine that this Great Instauration is a
thing infinite and beyond the power of man." He concedes,
however, in continuing, that the work will not be completed in
our generation, but will have to be taken up by another; and
there is evidence that longer study diminished his confidence.
The Inductive Theories.
21
Had Bacon brought his exposition of method to its completion,
his theory might, on more than one point, have come closer to
modern ideas. In the Novum Organum (I, XIV), we find a
hint of Dr. Whewell's doctrine of the explication of concep¬
tions, when Bacon asserts that the only hope of knowledge lies
in a true abstraction from facts, in the formation of a correct
notion; and in th§ second division of his method, that of fram¬
ing new experiments under the guidance of generalizations
already reached, we might have found, had it been completely
treated, a fuller recognition of the necessity of a proper verifi¬
cation.
Turning now to the theories of Scientific Method advanced
by Dr. Whewell, we find that according to him " our knowledge
consists in applying Ideas to Facts," (Novum Organum Reno-
vatum II, 1,1), and " the conditions of real knowledge are, that
the ideas be distinct and appropriate and exactly applied to
clear and certain facts."
The steps by which our knowledge is advanced are those by
which one or other of these two processes is rendered more
complete, by which conceptions are made more clear in them¬
selves or by which the conceptions more strictly bind together
the facts." The two processes he calls "the Explication of
Conceptions" and "the Colligation of Facts." "Man is the
Interpreter of Nature, Science its right Interpretation," (Hist.
Sc. Ideas, Book I, Ch. I). "The senses place before us the
characters of the Book of Nature," (Ibid Ch. II), but the alpha¬
bet by which they are to be read " consists of the Ideas exist¬
ing in our own minds," (Ibid Ch. III). "The antithesis of
Sense and Ideas is the foundation of the Philosophy of Sci¬
ence," (Ibid Ch. IV). These Ideas are "certain comprehen¬
sive forms of thought, as space, number, cause, composition,
resemblance, which we apply to the phenomena, which Ave con¬
template," (N. O. E. II, II). Facts on the other hand are based
upon Sense ^though beside the pure perception they involve Ideas
unconsciously. " The special modifications of Ideas which are
exemplified in particular facts" Dr. Whewell terms " Concep¬
tions; as a circle, a square number, an accelerating force ... a
22
Colorado College Studies.
genus," (N. O. E., Book II, Ch. II). "These conceptions must
be as it were carefully unfolded so as to bring into clear view
the elements of truth with which they are marked by their ideal
origin," (Ibid). The Explication of Conceptions has been
effected in the history of Science by means of discussion, the
conflict of opposing views, and has sometimes been marked
by the establishment of a Definition. But when the Definition
involves the explicit predication of certain attributes of the
thing named, the increase of knowledge is of matter of fact and
cannot be called simply the Explication of a Conception,
(Ibid).
" Induction is the process of a true colligation of facts by
means of an exact and appropriate conception;" "not the mere
sum of the facts, but the facts seen from a new point of view,"
( N. O. E. II, V.) " The conceptions by which facts are bound
together are suggested by the sagacity of observers," (N. O. E.
II, Ch. IV), a sagacity which cannot be taught (Ibid).
" When the theory of any subject is established the observa¬
tions and experiments which are made in applying the science
to use and to instruction supply a perpetual verification of the
theory," (N. O. E., Book III, Ch. IX).
Dr. Whewell's views on Induction are thus seen to result
directly from his theory of knowledge, his idea as to the manner
in which the objective and subjective elements. Sense and Idea,
join in perception; and their full discussion belonged rather to
Philosophy than to Logic. The position taken is intermediate
between the a priori introspective theory of the investigation
of the Universe and that simple observation, cataloguing and
combination of external facts which Bacon gives as the normal
method of scientific inquiry. Our progress in knowledge must
entirely depend, according to Dr. Whewell, upon the observa¬
tion of facts and the verification of our generalizations by com¬
parison with them; but it is the imagination of the investigator
that supplies the inductive guess to be verified. To his powers
of observation must be joined a natural sagacity capable of giv¬
ing birth to a colligating conception which shall on verification
prove to be the appropriate one.
The Inductive Theories.
23
Turning to the theory of Mill we find a definition of induc¬
tion more nearly like that with which our investigation began.
" Induction " according to him, " is that operation of the mind
by which we infer that what we know to be true in a case or
cases is true in all cases which resemble the former in cerl^in
assignable respects." The conclusion of an Induction is a uni¬
versal proposition: and there are two elements in the inductive
process; one the discovery of the generalization, the other its
proof. To which correspond two branches of the Logic of In¬
duction, one concerned with the process of discovery, the other
with the conditions under which generalization is legitimate;
the Logic in a word of Discovery and of Proof.
To the subject of inductive validity, that is the Logic of
Proof, Mill devotes special attention. Let us endeavor to
sketch his view of the conditions under which an observation
of particular fact warrants a general conclusion.
* In the first place a process which ends in the establishment
of universal propositions implies that Nature is such that uni¬
versally true assertions can be made regarding it.
Conceiving of the universe, therefore, as a realm of Law
throughout, we may proceed to investigate the conditions un¬
der which we may form generalizations with respect to it.
Along with the uniformity that Nature exhibits is exhibited
also most immense variety. While certain kinds of phenomena
occur with complete regularity, others show a less degree, and
in many we can discover no uniformity whatever. Generaliza¬
tions from various kinds of phenomena will therefore possess
very different degrees of trustworthiness. But if in our inves¬
tigations we are led to see that a given uniformity A is so con¬
cerned with a uniformity of a mere regular kind, B, that B must
be false if A is, A becomes at once a generalization of the same
value as B. Such a standard generalization is supplied,
according to Mill, by the principle of causation. Of the two
ways in which phenomena may accompany one another in time,
co-existence and sequence, the latter has been observed to exhi¬
bit complete regularity. The Principle of Causation is the
statement of the fact that events are not combined indefinitely
24
Colorado College Studies.
in various ways as antecedent and consequent, but tbat there are
strict limits, never overpassed, to the variety of these combina¬
tions. A given antecedent never occurs but with a certain con¬
sequent. That a certain consequent, however, may have several
alternative antecedents is recognized by Mill under the expres¬
sion Plurality of Causes. The result of the fact of Causation is
that any sequence of phenomena once definitely ascertained
since it must be general unless causation is false, rests not upon
its own evidence but upon that of causation. But causation is
an uniformity in which there has never been observed a break;
therefore the evidence for any sequence once observed is the
evidence for an absolute uniformity, and as far as its proof is
concerned the sequence may be considered to be an absolute
uniformity—a law of Nature. At once that whole body of
science springs into being which is concerned with the search
after cause and effect. A considerable portion of Mill's discus¬
sion on Induction relates to the conditions of this inquiry; and
includes a description of four Experimental methods and of a
combined method of Induction, Deduction and Verification
which must he states be a main reliance in investigating com¬
plex phenomena.
We have seen that when a sequence is once ascertained, the
generalization from it will rest on the firmest possible basis of
evidence, uncontradicted experience. Now if phenomena are
not conjoined in they are co-existent; and the question arises
as to the trustworthiness of generalizations of co-existence.
It is evident that whatever uniformities of co-existence are im¬
plied in ascertained laws of sequence will partake of their evi¬
dence. But in co-existences generally, we do not find that abso¬
lute regularity which marks sequences. Bacon'siidea that every
Nature has its accompanying form is not borne out by facts.
We are thus left without the standard generalization which gives
its evidence to the weaker conclusions of our observation and
experiment. There do exist indeed, in the laws of number and
space, absolute uniformities of co-existence; but the generaliza¬
tions which must be true unless the laws of number and space
are false, are simply truths of number and space, and outside of
The Inductive Theoeies. . 25
the domain of mathematics, therefore, we must look elsewhere
for inductive inquiry.
Mr. Mill here introduces his doctrine of Natural Kinds, ac¬
cording to which there are in Nature classes of objects whose dis¬
tinguishing common properties are innumerable. Among such
Natural Kinds, possessing countless properties in common which
are not possessed by other objects, we find the chemical elements
as sulphur, phosphorus, etc., and also animals and plants, while
white things or cold things are examples of classes which are
probably united by only the single property whiteness or cold¬
ness. In many departments of nature these Natural Kinds
will be marked out for us by their common possession of mul¬
titudes of qualities; and as this fact makes it very likely that
an observation will hit upon generic qualities, an observed uni¬
formity of co-existence may be generalized to the limits of the
Kind with some degree of assurance. And especially will this
be so if the qualities are of a kind which we have generally
found to be generic.
In closing his discussion of Induction, Mill devotes some
attention to the question as to what degree of credence, if any,
is to be given to a generalization when we have none of the
foregoing aids in estimating its worth, but when we know
simply the number of cases of the uniformity which have been
properly observed.
To what degree can we eliminate chance; how far can we be
sure that a certain run of coincidences is more than casual. His
first conclusion is that the mere number of observations gives
no ground for a generalization; but he afterwards admits that
the probability of such a number of coincidences by chance is
calculable and if very small we have reason to infer from the
observations an empirical law.
The theory of Induction thus sketched considers the process,
as we have seen, to be that operation of the mind by which from
certain obsirved concomitances of phenomena we infer that one
of the concomitants is an unfailing sign of the other; and the
greater part of the theory has to do with the conditions under
which we are justified in making that inference. The theory
26
Colorado College Studies.
of Mill differs from that of Bacon, in being based upon a dyna¬
mic instead of a static conception of the universe, upon the law
of causation instead of the principle of forms; but, on the other
hand, both in its general spirit and in the special provision for
" rejections and exclusions " embodied in the four experimental
methods, it incorporates the essential part of Bacon's reform.
We have seen that the first effort to discriminate a valuable
from valueless forms of inductive inference was made by
Socrates. His dialectic was an attack upon the ideas which
had grown up in men's minds as a result of uncritical general¬
ization; what he condemned was the habit of leaping to an
inductive conclusion, which is thenceforth held, untested by
comparison with fact, as a permanent part of our mental furni¬
ture.
In Bacon's theory this element of negative criticism became
of overshadowing importance. The participation of the imagi¬
nation in the search after truth was reduced to insignificance,
and inductive investigation became a simple process of boiling
down facts for their solid residuum.
In the theory of Whewell the inductive guess received
recognition as a necessary part of the normal process. Ac¬
cording to modern views therefore true induction involves both
that action of the mind in leaping to a conclusion which when
it acts alone leads to the false and prejudiced notions which
both Socrates and Bacon combated; and a testing of this sug¬
gestion by its confrontation with further fact obtained by
observation or experiment.
The contribution of Mill to the discussion of Inductive
inference embraced an elaborate theory of its validity. This
he made to depend chiefly on the law of Causation and the
principle of Natural Kinds; although he admitted that some
slight independent foundation is given an inductive conclusion
by purely mathematical considerations of Probability.
A MATHEMATICAL TEXT-BOOK OF THE LAST
CENTURY.
BY FLOBIAN CAJORI.
In the early days of Harvard and Yale, mathematics (includ¬
ing arithmetic, geometry and surveying) was studied during the
last year in college and was, seemingly, looked upon as being a
crowning pinnacle rather than a foundation stone of college
education. Algebra was an unknown science to the early stu¬
dents of Harvard and Yale. The exact date when it began to
be taught it is difficult to ascertain, but it appears that Harvard
existed about 100 and Yale 40 years before algebra came to be a
part of their respective college courses.
At William and Mary College in Virginia, it was taught ear¬
lier than at either of the two oldest New England colleges.
Hugh Jones was one of the early mathematical professors there.
In his book, "The Present State of Virginia," published in
1724, he gives a list of the school-books which he wrote, men¬
tioning among others, " Accidence to the Mathematick, espec¬
ially to the Arithmetick in all its parts and applications, Alge¬
bra, Geometry, Surveying of Land, and Navigation." These
were not printed, but existed only in manuscript, and were very
short' and elementary. Jones's history shows that algebra was
taught at William and Mary before 1724.
At Harvard algebra was not taught in 1700, for Rev. John
Barnard, who graduated that year, states in his autobiography
that he was " an utter stranger to " this science, though he had
some familiarity with geometry and trigonometry.* Wad-
worth's Diary (p. 27) gives the mathematical studies for 1726,
but algebra is not mentioned. No conclusive evidence has, in
♦Barnard's American Journal of Education, Vol. XXVII, p. 540,1877.
28
CoLOEADO College Studies.
fact, been found that algebra was studied at Harvard before
1786. A diary kept by a student in that year makes it certain
that it was taught then.* It is exceedingly probable, however,
that this branch had been part of the college course for at least
fifty years preceding this date. Peirce, in his history of Har¬
vard (p. 237), says that in the early part of the presidency of
Dr. Holyoke (1737-1769), "and probably many years before,"
the text-books were the following: Ward's Mathematics, Grave-
sand's Philosophy, Euclid's Geometry. Now, AVard's Mathe¬
matics contained a chapter on algebra, as we shall see pres¬
ently. But that in itself can hardly be considered conclusive
proof that algebra was taught then. Ward's mathematics may
have been studied only in parts. It contained, for instance, a
chapter on geometry, but the regular text-book in that subject,
Peirce tells us, was Euclid and not Ward.
At Yale, algebra was probably introduced in 1742. Our rea¬
sons for this belief are as follows: In a memoir of Samuel
Hopkins, who was a Yale graduate of 1741, it is stated that when
he was a student, metaphysics an(i mathematics found their
place in the fourth year.f This statement agrees with what
we know of the earliest course of study at Yale, in which
mathematics was taught only in the Senior year, and which
embraced arithmetic, geometry, surveying, and astronomy.
So long as mathematics was not taught earlier in the course,
it is not likely that algebra was added. The addition of
algebra to the four mathematical subjects already enumera¬
ted would make the amount of the year's work in mathe¬
matics incredibly great. It is not likely, then, that alge¬
bra was studied before 1741 at Yale. But in 1742 we wit¬
ness a complete revolution in the course of study. In that year
the rector advises students to pursue a regular course of
academic studies in the following order: " In the first year to
study principally the Tongues, Arithmetick, and Algebra; the
second. Logic, Ehetoric, and Geometry; the third, Mathema-
ticks and Natural Philosophy; and the fourth. Ethics and
• Old Cambridge and New, by Amory: North American Review, Vol. lu, 1872, p. iis.
tProf. E. A. Park s Memoir of Samuel Hopkins, Second Edition, p. 13.
Text-Book of Last Centuby.
29
Divinity."* This is, to our knowledge, the first appearance
of algebra at Yale. President Stiles, in his diary for Novem¬
ber 9, 1779, gives a list of books recited in the several classes
at his accession to the presidency. Ward's Mathematics is
in this list.t It thus appears that this was used as a text¬
book at both Yale and Harvard. It was studied also at Dart¬
mouth. At the institution, now called the University of
Pennsylvania, instruction was given by lectures, but Ward's
Mathematics was in the list of books of reference recom¬
mended to students.
Ward's Mathematics was once a favorite text-book in Amer-
can colleges. It was used as early as 1737 at Harvard and as
late as 1787 at Yale and Dartmouth. It was, probably, the first
book from which American students learned algebra. A brief
description of this now rare book may, therefore, be of some
• interest to teachers of to-day.
Ex-President D. AVoolsey speaks of the author of Ward's
Mathematics as the Ward who was " President of Trinity Col¬
lege, Cambridge, and Bishop of Exeter."J The only Ward
answering this description is Seth Ward, but I shall prove that
the author of the book in question is not Seth Ward, but John
Ward. The latter wrote a book, called " The Young Mathema¬
tician's Guide" and a "Compendium of Algebra." The latter
work treated very briefiy of that which was " fully handled at
large " in the part on algebra in the former work. We have of
John Ward also a posthumous work containing a "New Method
of Navigation of Parallel Parts"; "Compendiums of Prac¬
tical and Speculative Geometry and of Plane Trigonometry."
I have consulted several biographical dictionaries, as well as a
Life of Seth Ward,§ but have found no mention of a book or
books by him, that are called " Ward's Mathematics," or that
embrace those subjects that are most likely to have been taught
to students just entering upon the study of mathematics. The
m
* Yale Biographies and Annals, 1701-1745, by Franklin Bowdlteh Dexter,
t Yale College; A sketch of Its History, by William L. Kingsley, Vol. II, p. 498.
X Yale College; A Sketch of its History, by William L. Kingsley, Vol. II, p. 489.
S Life of the Eight Reverend Seth, Lord Bishop of Salisbury, by Waller Pope, 1697,
London.
30
colobado College Studies.
only possible exception to this is his " Idea Trigonometriae
demonstrata in usum juventutis," 1654. His only other math¬
ematical and astronomical writings, of which I have any knowl¬
edge, are, "Astronomia Geometrica, London, 1656 " Praelectis
de Cometis"; "Inquisitio in Ismaelis Bulialdi Astronomiae
Philolaicae fundamenta "; and a tract on Proportion. It is not
likely that mathematical books written in Latin were read in
our colleges at as late a" date as " Ward's Mathematics " is known
to have been used. Let it be remembered, moreover, that Seth
Ward wrote the above works before the name of Newton had
become known to science. John Ward, on the other hand,
wrote his books half a century later and is, therefore, more
likely to be the author studied in this country. Wherever we
have seen this book mentioned in the curricula of American
colleges, it was always called " Ward's Mathematics." The bap¬
tismal name of the author was never given. This shows that
there was only one Ward (either John or Seth) whose mathe¬
matical works were known and studied in our colleges. Now,
Benjamin West, Professor of Mathematics in Brown University
from 1786 to 1799, published in the first volume of the American
Academy of Arts and Sciences a paper " On the Extraction of
Roots," in which he offers improvements on "Ward's" method.
I have seen a copy of the "Astronomia Geometrica " in the Ridg-
way Library in Philadelphia, but have found nothing in it on
root-extraction. One would hardly expect to find anything on
it in Seth's Trigonometry or Proportion. John Ward, on the
other hand, treats of the extraction of roots in his " Guide," and
gives a " general method of extracting the roots of all single
powers." West takes two examples (two numbers, one of 14,
the other of 18 digits) from "Ward" and shows how the re¬
quired roots can be extracted by his method. Now, both these
examples are given in John Ward's "Young Mathematician's
Guide." This evidence in favor of John Ward's book may be
regarded conclusive.
The first edition of the " Young Mathematician's Guide "
came out in London, in 1707.* The fourth edition, 1724, con-
* An Essay upon Study, by John Clarke, London, 1731, p. 313.
Text-Book of Last Centuey.
31
tains a fine copper plate portrait of the author. The edition
whichr I examined was the twelfth. I give the title-page in
full, because a fair notion of the contents of the book may be
gained from it.
"The Young Mathematician's Guide; Being a Plain and
Easy Introduction to the Mathematicks, in five parts, viz.:
I. Arithmetick, Yulgar and Decimal, with all the useful
rules; and a general method of extracting the roots of all single
powers.
II. Algebra, or Arithmetick in Species; wherein the Method
of Eaising and Resolving Equations is rendered easy; and illus¬
trated with Variety of Examples, and numerical questions.
Also the whole business of Interest and Annuities, etc., per¬
formed by the Pen.
III. The Elements of Geometry contracted and analytically
demonstrated; with a new and easy method of finding the
Circle's Periphery and Area to any assigned exactness, by
one equation only; also a new way of making Sines and
Tangents.
IV. Conick Sections wherein the chief properties, etc., of
the Ellipsis, Parabola, and Hyperbola, are clearly demons¬
trated.
V. The Arithmetick of Infinites explained, and rendered
easy; with its application to superficial and solid geometry.
"With an appendix of Practical Gauging.
By John Ward.
The 12th Edition, carefully corrected and improved by Sam¬
uel Clark. To which is added a supplement, containing the
history of Logarithms, and an index to the whole work.
London, 1771."
From the preface we quote the following: " I believe I may
truly say (without vanity) this treatise hath proved a very help¬
ful Guide fo near five thousand persons; and perhaps most of
them such as would never have looked into mathematicks at all
but for it" ... . "And not only so, but it hath been very well
received amongst the Learned, and ( I have been often told) so
32
CoLOBADO College Studies.
well approved on at the Universities, in England, Scotland, and
Ireland, that it is ordered to be publickly read to their pupils
)»
Like all English arithmetics of that time, that of Ward con¬
tains rules and illustrations without reasoning. In the chapter
on algebra he first explains the negative sign as meaning al¬
ways subtraction, just as in arithmetic, but he tacitly intro¬
duces later on " negative quantities "—thus using the negative
sign in a different sense without explaining that fact to the
pupil. Until about fifteen or twenty years ago all our algebras
contained that very defect, of attributing to the minus sign by
definition only one meaning, but of actually using it in two
senses.
Ward shows how to expand a binomial with a positive inte¬
gral exponent " without the trouble of continued involution,"
and then makes the following interesting remarks: "Now from
these considerations it was, that I proposed this method of rais¬
ing powers in my Compendium of Algebra, p. 57, as wholly new
(viz., so much of it as was there useful) having then (I profess)
neither seen the way of doing it, nor so much as heard of its
being done. But since the writing of that Tract, I find in Dr.
Wallis's History of Algebra, p. 819 and 331, that the learned Sir
Isaac Newton had discovered it long before."
The third part, on Geometry, is quite inferior in point of
precision and scientific rigor. After the definitions follow 20
problems, intended for the excellent purpose of exercising " the
young practitioner," and bringing "his hand to the right man¬
agement of a Ruler and Compass, wherein'I would advice him
to be very ready and exact." Then follows a collection of 21
" most useful theorems in plane geometry demonstrated." This
part is semi-empirical and semi-demonstrative. A few theorems
are assumed and the rest proved by means of these. The theo¬
rem, " If a right line cut two parallel lines, it will make the
opposite angles equal to one another " is proved by aid of the
theorem that " if two lines intersect each other, the opposite
angles will be equal." The proof is based on the Idea that
"parallel lines are, as it were, but one broad line," and that by
Text-Book of Last Centuby.
33
moving one of the parallel lines toward the other the figure for
the former theorem reduces to that of the latter. The next
section contains the algebraic solution of 20 geometric problems.
Part IV, on Conic Sections, gives a semi-empirical treatment
of the subject. Starting with the definition of a cone, it shows
how the three sections are obtained from the cone and then
gives some of their principal properties. In this as in Sll Eng¬
lish books of the 18th century, analytical geometry was
neglected. The Conic Sections were then studied in England
and America only by the synthetic method. It was not till the
close of the first quarter of this century that analytical geometry
began to be introduced into our American colleges.
The part on " Arithmetick of Infinites" is interesting, for
it constitutes a sort of integral calculus, such as was employed
by Wallis, Cavalieri, Fermat, and Eoberval before the inven¬
tion of the Differential and Integral Calculus of Newton and
Leibniz. Ward seems to have known nothing of Fluxions.
The first edition of Ward's book appeared in 1707. Newton
published the first edition of his Principia in 1687, but his
Method of Fluxions was not published till 1736, though written
in 1671.
Were those half-developed, pre-Newtonian methods ever
studied in American colleges? It is possible that they were on
some rare occasions, but we have no evidence to that effect.
In the essay on the history of logarithms we look in vain for
any statement pointing out the difference between natural loga¬
rithms and those invented and published by Napier. The two
have been considered identical by many English and Ameri¬
can writers, down to the present day, and it is probable that
text-book compilers will persist in this error for many years to
come.
Though Ward's Mathematics treated of five broad subjects,
it covered only,475 pages, or not quite so much as is given now-
a-days to the elementary presentation of any one of these sub¬
jects. The type in this old book was coarse. From this we
may judge how meagre the knowledge to be derived from
Ward's Mathematics really was.
3
HORACE, CD. Ill, 1, 34.
BY GEOBGE L. HENDBICKSON.
Contracta pisces aequora sentiunt
iactis in altum molibus: hue freqMns
oaementa demlttlt redemptor
cum lamuUs domlnusque terrae
tastidiosus.
The interpretation of the word frequens in nearly all the
editions, both German and English, which I have seen seems to
me strained and manifestly incorrect. It is as follows, as for
example in Nauck:
" Frequens cum famulis lauft auf dasselbe hinaus wie fre¬
quens famulis, d. h. famuloriim frequentia stipatus. Die be-
gleitenden Diener sind zugleich dasjenige, wodurch die fre¬
quentia bedingt und bewirkt wird." This is the explanation
adopted by Orelli, Doering, Page and others, though nearly all
admit that it is rather strained. Wickham (whether following
other authority or not I do not know) goes a step further and
says: "Horace represents the builder {redemptor), with a large
staff of assistants {frequens), the servants of the owner {famu¬
lis), and the owner himself, as all engaged in hurrying on the
work." The absurdity of this, however, is palpable. Macleane
after giving the above explanation says: "Others say it means
frequenter. I think it means this or ' many a redemptor.'"
Mr. Page also says: "Without the addition of the words cum
famulis the phrase frequens redemptor would certainly mean
' many a contractor.'"
Without commenting further on these interpretations I
would call attention to a passage in Varro de L. L., 7, § 99
(Spengel). Apud eundem {i. e., Plautum) quod est:
mi frequentem operam dedistis,
valet assiduam. This passage seems to have been over-
Hobace, Od. Ill, 1, 34.
35
looked by commentators, but it gives the clue to the correct
interpretation of the Horace passage in hand. The quota¬
tion from Plautus is found in Cistillaria 1, 1, 7, where it is
correctly interpreted in the periphrasis of the Delphin edi¬
tion, as follows: "Mihi exhibuisiis sedulam operam, omissis
ceteris negotiis." Applying this meaning of frequens to the
phrase frequens redemptor it will at once be seen how much
easier and fitter it is than the doubtful explanations given. No
one surely would have found difficulty with the phrase redemp¬
tor assiduus or redemptor sedulus, which, as it appears, is ex¬
actly the meaning of frequens redemptor. Kiessling, while he
does not comment on the word frequens, nor give any refer¬
ences for this use of it, seems from the following translation to
understand it in the sense of assiduus or sedulus: "UnablSssig
{frequens) versenkt der Unternehmer mit seinen Werkleuten
die Bruchsteine in die Fundamente, etc."
QUINTI CICERONIS COMMENTARIOLUM PETITIONIS
XI, § 43.
BY GEORGE L. HENDBICKSON.
Prodfest qiiidem vehementer nusquam discedere, sed tamen hie fructus est assidui-
tatis, ,non solum esse Eomae atque In foro sed assi.due petere, saepe eosdem appellare,
non committere ut quisquam possit dicere, quod elus consequi possls, si abste non sit
rogatum et valde ao diligenter rogatum.
This is the reading of Buecheler, and also of Baiter, except
that the latter writes quoad eius for quod eius. I wish to call
attention, however, to the words sed tamen, which so far as I
can see have no meaning at all in this connection; for in the
sentence hie fructus est assiduitatis there is certainly no idea
adversative to the statement, prodest quidem vehementer nus¬
quam discedere. To admit of the adversative particles sed
tamen in this sentence the preceding one must have contained
some such idea as this: discedas fortasse interdum, sed tamen
hie fructus est assidmitatis. It seems to me evident, therefore,
that sed tamen cannot be correct. The connection after prodest
quidem vehementer nusquam discedere demands, if anything, a
reason for the statement, and I would therefore emend to sed
quoniam or siquidem, neither of which, I think, would be paleo-
graphically improbable.
"ONE OF THE CHEAT CITIES."
Denver is to be one of the four great Cities of the United
States.
Her great natural resources, her vast amount of enterprise,
energy, and money are all conspiring to fulfill this prediction.
In consequence of the general belief that it is in the condition
of things to bring about this result, vast amounts of money from
all over the country are constantly coming here, and being in¬
vested in Real Estate and active enterprises.
Property is cheaper in Denver than in any other City in tlie
U. S. of the same size and prospects.
Investments made now must earn large profits.
Broadway Property our specially. Special Bargains in 80
and 40 Acre tracts; also 5 Acre Blocks, J and I Blocks in South
Broadway Heights.
Buy a 5 Acre Block while you can get it cheap. It will
double in value in a few years.
Send or call for maps and circulars.
Jt)e Broadu/ay Ipuestmept Qd.,
THOS. FITZGERALD, President, 915 17th Street,
DENVER, COLO.
Colorado Coi.i.hgr.
*
(Colorado 5pri9^s, <?olo.
The College offers two courses, leading, respectively, to the
degrees of Bachelor of Arts and Bachelor of Philosophy. In the
Ph. B. Course, Greek is omitted and more attention is given to
the sciences and modern languages. The College has a good
library and well equipped laboratories. Special winter courses
are given in assaying, blowpiping with determinative mineral¬
ogy, qualitative and quantitative analysis. The facilities for this
course are unusually tine.
The various courses of study have now been so arranged and
the faculty so enlarged that Colorado College offers the same edu¬
cational facilities as the Eastern Colleges. For catalogues, address
WILLIAM F. SLOCUM, Pres.
The Cutler Academy,
Under the auspices of the Colorado College, gives students a
thorough preparation for admission to the Freshman class of any
college in the country. Correspondence concerning the Cutler
Academy should be addressed to the Assistant Principal,
GEORGE L. HENDRICKSON.
The location of the College is unsurpassed. Col¬
orado Sjtrings has a world-wide
reputation as a
Students forced by pulmonary or malarial troubles to discontinue
their studies in the East, pursue college courses here successfully and
at the same time make a permanent gain in health. A recent number
of the Colorado School Journal speaks of this college town in the follow¬
ing words: " No point in our State ever combined as many advantages for
the establishment, growth and greatness of a college as does Colorado
Springs. It is manifestly the point about which scholars and students,
men and women of culture, wealth, and leisure will reasonably gather."
8.1
'19
r
1
SECOND ANNUAL PUBLICATION.
Ul
OLORADO COLLGE STDDIES.
Papers read before the Colorado College
Scientific Society.
COLORADO SPRINGS, COLO.,
1891.
J
SECOND ANNUAL PUBLICATION.
COLORADO COLLGE STDDIES.
Papers read before the Colorado College*
Scientific Society.
COLORADO SPRINGS, COLO.
1891.
CI >3
C
V. Zy
printed and bound
AT THE OFFICE OF
The Register Publishing Company.
Ube Inlanb pres6.
ann arbor, michigan.
OFFICERS, 1891-1892.
President, . . , Peofessoe William Steieby
Vice-Presidents, Me. Louis B. Eheich and Miss M. B. Mann
Secretary, . . . Peofessoe Floeian Cajoei
Treasurer, . . Peofessoe Geoeqe L. Hendeickson
PLACE OF MEETING.
PALMEB HALL, COLOBADO COLLEGE.
TABLE OF CONTENTS.
page
Announcement 7
witchokaft Among the hindus Dr. H. W. Magoun. 9
Protection of Congressional Minorities. .. W. 31. Hall. 20
Pulsations in the Aortic Arches of the Earthworm. ..
3Iiss 31. B. 3fann. 20
Dialectical Studies in West Virginia
Dr. Sylvester Primer. 28
The Study of Diophantine Analysis in the United
States F. Caiori. 39
The Elliptic Functions Defined Independently of the
Calculus F. H. Loud. 48
On Two Passages in the Crito Dr. H. W. 3£agoun 82
Calibration of Burettes D. J. Carnegie. 87
On a Passage in the Frogs Dr. H. W. 3Iagoun. 91
Note on the Had ley-Allen Grammar
Dr. H. W. 3Iagoun. 93
Historical Note on the Differentiation of a Logarithm.
F. Cajori. 90
A Mathematical Error in the Century Dictionary
F. Cajori. 97
ANNOUNCEMENT.
During the past year the Colorado College Scientific Society
secured a considerable number of exchanges from other associa¬
tions of similar character. It is hoped that this year the pres¬
ent list of exchanges may be greatly enlarged.
The past year has been a prosperous one for the Society.
Its meetings have proved to be of great mutual benefit to its
members. The following is a complete list offpapers and re¬
ports presented to the society:
October 14, '90—
The Abandonment of Children in Ancient Greece and
Rome. George L. Hendrickson.
Recent Researches in Magnetism. Florian Cajori.
November 14, '90—
Witchcraft Among the Hindus. Dr. H. W. Magoun.
December 11, '90—
Protection of Congressional Minorities. W. M. Hall.
Pulsations in the Aortic Arches of the Earthworm. Miss
M. R. Mann.
Solidarity of the Race. J. M. Dickey.
January 13, '91—
Dialectical Studies in West Virginia. Dr. Sylvester
Primer.
Men for the Hour. H. J. Barber.
February 10, '91—
Germ Theory of Disease. Miss M. R. Mann.
On Two Passages in the Crito. Dr. H. W. Magoun.
\
Announcement,
March 24, '91—
On van't Hoff's Law of Osmotic Pressure. (Published in
the Chemicl News April 10, '91). D. J. Carnegie.
The Aryan Question. Dr. Sylvester Primer.
April 21, '91—
An Interpretation of the Pourth Gospel in the Light of
Gnostic Philosophy. President William P. Slocum.
The Elliptic Punctions Defined Independently of the Cal¬
culus. P. H. Loud.
The Study of Diophantine Analysis in the United States.
P. Cajori.
May 12, '91—
Cross Katio. B. E. Carter, Jr.
Calibration of Burettes. D. J. Carnegie.
June 9, '91—
On a Passage in the Progs. Dr. H. W. Magoun.
Note on the Hadley-Allen Grammar. Dr. H. W. Magoun.
Historical Note on the Differentiation of a Logarithm. P.
, Cajori.
A Mathematical Error in the Century Dictionary. P.
Cajori.
WITCHCRAFT AMONG THE HINDUS.
BY H. W. MAGOUN.
The mysterious always arouses curiosity, and the mysterious
is no small element in magical practices. Witchcraft has never
lacked its devotees. Its stronghold has always been among the
ignorant and superstitious; but men of learning, and even emi¬
nence, for their time, have firmly believed in its reality, and have
felt it a duty to search out and punish those who had dealings
with the evil one. Even at the present time, in some parts of
the world, people of intelligence still cling to a belief in the
existence and power of witchcraft; its literature still flourishes
among them, and its teachings are accepted as containing things
which are true and worthy of respect.
While at the Johns Hopkins University, three MSS. wero
put into my hands which contained a practice called the A s u r i-
K a 1 p a h. The MSS. all belonged to the A t h a r v a-Y e d a
and were known as parigistas, or supplementary writings.
Their contents were as yet unknown. Two of the MSS. con¬
tained each a very brief outline of a rite which began with a
spell; the third contained three versions of the same thing, one
of them being much fuller than any of the others and partaking
of the nature of a commentary. This MS. was really the key
to the entire practice; but it presented enormous difficulties at
the start, for the writing was something astonishing. Diligent
comparisons of similar passages gradually established the sense
of the greater part of the document, and an outline of it will be
given below. The results of my work were published in the
American Journal of Philology for July, 1889,
under the title. The Asuri-Kalpa; a Witchcraft Prac-
2
10
('oloradd CoJIt'tjr Sfiidiri^.
tice o£ the A t li ar va-V e d a. lu the preparation of the
above pa])er various items of interest had to be passed over.
They will form the chief part of the present article.
Born in a country where the excessive heat makes clear those
words of the psalmist, "The sun shall not smite thee by day
nor the moon by night," subject to many disorders of the digest¬
ive organs incidental to a hot country, surrounded by dangers
from re2)tiles of which we know next to nothing, suffering from
long continued drought, followed by terrific thunder and hail
storms, and without revelation, the Hindus were j)articularly
adapted to fall into the bonds of sujjerstition. In its iron grasp
they seem to have harbored no thought of inquiring into natural
phenomena; and, while develojjing abstruse and subtle i)hiloso-
phical doctrines, keen grammatical insight, and a system of
phonetics which is the basis of the science to-day, they remained
utterly unscientific in all matters ijertaining to the material
world, and were perfectly heljjless to explain coiTectly even the
most simple process of nature. They looked upon the wonders
of creation as children might, and in each new phenomenon they
saw a living sentient being manifesting himself for the good or
harm of the beholder. The cloud was a huge serpent keeping
back the rain, the lightning was the weapon of Indra smiting
"the serpent and compelling him to allow the rain to fall, and an
•eclipse was an attempt by the demon R a h u to swallow the sun
•or moon. A g n i or fire was a god born of two sticks. Rubbing
the sticks together, they prayed earnestly for his appearance,
and the resulting fire was regarded as an answer to prayer. If
some doubter muttered spells instead, the spells were the cause
of A g n i' s coming in his eyes and the step to the practice of
witchcraft was a short one.
The use of spells or imprecations was accepted by the
orthodox Hindus as proper in certain cases, and the M a n a v a-
Dharmagastra states definitely that the hymns 'of the
A t h a r V a-V e d a are to be used by a Brahman as a weapon
against his enemies. The hymns of this Veda were also used
WiffJicraff Aijioiig fJic HIikIiik.
11
ill the practice of medicine and were muttered over the patient
while certain rites were performed with such materials as mud,
gravel, curds, sour-milk, melted butter, and cow-dung. As Sir
Alfred Lyall puts it, "We talk of a dose actiug 'like a charm,'
while the Hindu employs a charm to act like a dose." Brah-
mans were forbidden to practice medicine, unless compelled by
necessity, however, so that even they recognized the uncanny
element in it.
The faith in .spells finally became so great that it was be¬
lieved that even the gods must heed them when properly used.
.In the Laws of M a n u, however, which were cited above,
occurs the statement that witchcraft or abhicara practices
are secondary crimes; so that, while their outward forms, to our
eyes at least, are so near alike that it is almost impossible to
distinguish between them, the Hindus recognized a clear and
sharp difference in the two. When the rites are used for harm,
independent of, or in spite of, the gods, the practitioner is an
enemy of the gods and a worker of black magic. Anything
wrong in the community lies at his door and he must be pun¬
ished, for he is desti'oying the power of the Brahmans' prayers
by his arts.
If two sticks, with the help of a few spells would produce
fire, the inference was that two knives crossed on a threshold or
a red rag put over a door must harm the occupant of the house
when imprecations were added. If the strange signs caused
the person to tremble or turn pale, the concealed sorcerer was
convinced that his intended victim was feeling his power and he
believed in his charms accordingly.
The religious Hindus, while accepting these things as true,
felt bound to propitiate their gods by an austerity painful to
think of; but this asceticism was supposed to compel the gods
to reward them nolens volens, so that the difference looks
small to us in point of fact. The theosophic speculations of this
class reached their culminating point in the teaching of the
Tedantas which hold that there is one ultimate and only god,
12
Colorado College Studies.
unknown and unknowable, by whom they are finally to be ab¬
sorbed. The sceptical Hindus naturally drifted into witchcraft,
and the pretentions of the professional wizards are by no means
modest. It is not an uncommon thing for a Hindu, when his
own prayers and those of the Brahmans, hired for the purpose,
are unavailing, to go to some practitioner of magic who rarely
fails to promise all he wishes and does not scruple sometimes to
even administer poison, if need be. There are stories of those
who invoked genii; but did not know how to control them and
were torn to pieces in consequence. That, however, matters little.
The popular belief in witchcraft is so general that there is
scarcely a town in central India of any size, says Lyall,* that has
not a hereditary servant whose duty it is to ward off impending
hail-storms by watching the motion of water in certain pots,
muttering incantations and dancing about with a sword. This,
however, is white magic, not black.
The sorcerer has an enemy in the witch-finder who volun¬
teers, for so much money, to tell who has bewitched any sick or
unfortunate person. The method called S a t a n e is as follows:
The witch-finder sits on the ground with a branch of the Bale-
tree opposite. Eice is handed him which he eats in the name
of each village. When the name of the right village is men¬
tioned, he throws up the rice. The families of the village are
then treated in the same way; and, lastly, the individuals of the
family which has been chosen as guilty. A sufficient sum will
induce him to doubt the result and try it again. Charreen
is a similar process. A stone is hung on a string with the vil¬
lages, families, and individuals marked on it; the names are
mentioned and the guilty one is selected by the vibrations of
the suspended rock. The sorcerer who was thus detected had
to put his tongue to red-hot iron nine times unless sooner burnt.
InGobereen, water, oil, and cow-dung are mixed and brought
* Sir Alfred Lyall, Asiatic Studies, from which many of these
facts were gathered.
Witchcraft Among the Hindus. 13
to the boiling point; a ring is then dropped in which must be
found and brought out by the hand, while the person invokes
the deity for protection from burning.
The use of fire has been believed in by nearly all races as a
test for witchcraft, the supposition being that the deity protects
the innocent by a miracle. The Hindus are no exception to the
rule. One fire-test was to require the magician to carry two
pounds and three-quarters of red-hot iron in the hands across
seven circles, each sixteen finger-breadths broader than the pre¬
ceding, and then throw it into a ninth, where it must burn some
grass. If he is burned he is guilty of causing the sickness and
must cure the person or die. The Manava-Dharma-
gastra (VII, 108), says that when a witness falls sick or
has a loss from fire within a week, it is because he has perjured
himself in his testimony. The same law-book (VIII, 114-16,
190) says: 'Let the judge cause him who is under trial to take
fire in his hand, or plunge into water, or touch separately the
heads of his children and his wife, and he whom the fire burns
not, whom the water does not reject from its depths, whom mis¬
fortune does not speedily overtake, shall have his oath received
undoubted.'
The common water-test is to fix a bamboo rod in a pond,
send the person to it, and require him to descend to the bottom
while an arrow is shot and brought back by a runner. If he
emerges before the arrow is returned, he is guilty. Another
test is to put the accused into one sack, a stone in another, and
throw the two tied together into running water. If the stone
rises while he sinks, he is guilty. The simple original method
which corresponds to the European, is to see whether the
accused will float or sink, the latter indicating guilt. The pun¬
ishment, especially as a result of the first method, is very severe.
If the guilty person is a woman, she may be roped up to a tree,
have a bandage of red-pepper tied over her eyes, and then be
swung to and fro in the air, or she may even be beaten to death
with rods from the castor-oil tree, which is supposed to be excel-
14
Colorado Cidlcijc tSfadicH.
lent for purging witchcraft, simply because auy slight indisposi¬
tion that could be removed by the use of the oil, was attributed
' to the power of witches. Smallpox or cholera are due, they
think, to the spells of witches also, since the gods do not stoop to
these things, though tliey have them in their poweis. It is the
producing of evil residts which makes the witches; for so long
as magic is used for good ends and the gods are still served, the
practitioners are not witches.
The literature of witchcraft in India has increased enorm¬
ously, especially in the vernacular, and it is to-day the
favorite reading of the people. The Asuri-Kalpa may
perhaps be taken as a fair s[)ecimen of this literature,
and a brief outline of its contents may be of interest. In
preparing for the fi s u r i-spell, a small, square piece of ground is
first cleared, then a triangular hole, measuring about a span
each way, is dug in the center, and the person puts on a red gar¬
ment and adorns himself with garlands of the red oleander, and *
an ornament of sandal-wood, supposed to represent the feet of
Visnu resting on a lotus. He then lies down on a woolen
blanket with his face to the east, toward which one angle of his
three-cornered fire-pot points, and offers an oblation of sugar
and melted butter, after which he mutters: " Om, obeisance to
End ra, om, O pungent one, thou of the pungent leaf, blessed
Asuri, reddish one, thou of the reddish garment, O daughter
of A t h a r V a n, non-terrific one, non-terrific wonder-worker,
so-and-so smite, smite, burn, burn, cook, cook, crush, crush, so
long burn, so long cook, until thou hast brought [him] into my
power. Amen.*
*om iiamo riidraya, om katuke katukajiattre sahhaga asvri rakte
raktavasase, atliarcancmja duliite 'ghore 'ghorakarmakarike, amukain
kana liana dalia dalia pai.u paca mantlia mantha tavad dalia tavat
paca yavan me vaijani anayali svalta. The whisper-spell which is an
extension of the first part of this formula, and consists mostly of
mysterious particles, reads as follows: —o?h kliin liriin qrim ksaum
Witchcraft Aihoikj the Hindai^.
15
For a woman the spell was somewhat longer, and a second
brief one is added: 'For her not a lunar-day, not a lunar-
mansion, not the kindling of a holy fire is decreed.'
Nest in order comes a nijasd ceremony, which is a sort of
consecration service, giving obeisance to each pair of thuynbs,
fore-fingers, etc., and to the two palms and backs of the hands-
It seems to be intended in this case as a propitiation of
Brudra. * Durgais then invoked, and mention is made of
kmum qrim hrim Mini om, katiqiattre siibliana amiri raktavamse
Hharvanasya dnhite 'yhore 'yJinre scalai, oni hlini hrim, etc., as at the
beginning. The Durga Puja l)y Pratapachandra Ghosha, contains
a long list of these particles used in pouring water into a conch-shell as
an act of worship. Keeping his s}'stem of transliteration, it is as fol¬
lows:—Ksham, Lam, Ham, Sam, Sham, Sam, Vam, Lam, Earn, Yam,
Mam, Bham, Bam, Pham, Pam, Nam, Dham, Dam. Th im, Tam. Nam,
Dham, Dam, Tham, Tam, Nam, Jham, Jam, Chham, Cham, Nam, Gham,
Gam, Kham, Kam, Ah, Am, Aum, Om, Aim, Em, Ltn, Lm, Em, Em, Um,
Um, Irn, Im, Am, Am, Mam,
* The Durga Puja, which is a book giving an account of the
religious worship of Durga, contains such a ceremony, called the
External Miitrika Nyiisa. Using the method of transliteration,
etc., which is employed, it reads as follows:—The rshi of this Matrika
mantra is Brahma, its metre is Gayatri, the deity Matrika sarasvati
[Indus Eiver], the consonants are the roots, the vowels are the Saktis
[powers], these are used in the Matrika Nyasa. With a flower Om
obeisance to Brahma Eshi in the head, Om obeisance to Gayatri
Metre in the mouth, Om to Matrika Sarasvati Devi in the heart, Om
to the consonant roots in the muladhara [root-holder], Om to the
vowel Saktis in the feet. Then meditate on Matrika: Help me, O !
goddess of speech, whose lips are parted by fifty characters [the letters
of the Sanskrit alphabet], whose arms extend to the knees, whose bosom
is well formed, whose forehead is emblazoned by the moon with all the
phases, whose breasts are as compact as they are lofty, and whose hands
hold the mudra [seal], the beadstring, a nectar-pot, and gift of knowl¬
edge, and who is white in appearance, and three-eyed.
Am to the forehead. Am to the mouth, Im to the right eye, Im to the
left eye, Um to the right ear, Um to the left ear, Km to the right nose
[nostrils], Em to the left nose, lm to the right cheek, Im to the left •
16
Colorado College Studies.
her ninety million bodily forms. The person now indulges in
a religious meditation (dhydna), in which he worships the
dsM?i-plant as a goddess called the fearless wish-granter. There
are three parts of this meditation to be used in the morning, at
noon, and at night respectively. In the first, he thinks of the
goddess as having a hook in her hand, as adorned with all
ornaments, having a gracious countenance, and as seated on a
serpent in the padmdsana position, i. e., with the legs crossed,
one hand on the hearth with the thumb up, the other on the
left thigh, and the eyes fixed on a point near the end of the
nose. The second is similar, but she has a sword in the hand
and a half moon crest. In the third, she has a ' red-stone' in
the hand, sits on a dead man, and wears garlands of mundd-
plant. A second version, given elsewhere in the MS., puts in a
discus, a trident, a white serpent, a white bull, etc., etc., and
describes the goddess as having three eyes, four mouths, a string
of pearls in the nose, and so on. *
cheek, Em to the upper lip, Aim to the lower lip, Om to the upper teeth,
Aumto the lower teeth. Am to the cerebrum. Ah to the right shoulder-
blade, Kam to the elbow, Kham to the wrist. Gam to the roots of the
phalanges, Gham to the phalanges, Xam to the nails, Cham to the left
shoulder-blade, Chham to the left elbow. Jam to the left wrist, Jham to
the roots of the left phalanges, Xam to the left nails. Tarn to the right
heels, Tham to the right knee-bone. Dam to the right ankle, Dham to the
roots of the phalanges. Lam to the tarsals. Similarly Tam, Tham, Dam,
Dham and Xam to the several parts of the left leg. Pam to the right
side, Pham to the left. Bam to the back, Bham to the navel. Mam to the
stomach. Yam to the heart, Kam to the right shoulders, Lam to the neck
bone. Vara to the left shoulders, Sam from the heart to the right hand,
Sham from the heart to the left hand, Sam from the heart to the right
leg. Ham from the heart to the left leg. Lam from the heart to the belly
Ksham from the heart to the mouth.
* A meditation or prayer of the Durga Puja may be compared,
with this, whidh reads as follows:—Om with locks of hair, braided and
flowing, and the forehead ornamented by the crescent moon, with three
eyes, with a face equal to the full moon in brightness, with a com¬
plexion of molten gold, well-formed and lovely eyed, full of the fresh-
Witchcraft Among the Hindus.
17
After this contemplation comes the chief practice of the
ceremony, the object of which, in the wotds of the MS., is the
desire to destroy, the destruction of an enemy, the slaying,
stupefying, making submissive and fixing like a post. The
person takes leaves and seeds of the dsurl* plant (black mus¬
tard) and grinds them into meal. An image of the person to be
subdued was then made from this meal with melted butter, sour-
milk, sugar (or honey), salt, or mustard-oil, according to the
caste of the victim—the mustard-oil was for an enemy—after
which the image was chopped up with some kind of a weapon
and burned in the fire-pot with kindlings of different woods
according to caste.
This practice was repeated one hundred and eight times—
eighteen per day—beginning with six in the morning, continuing
with six at noon, and ending with six at about sundown. The
proper meditation was used in each case. The morning form
helped in making submissive; that used at noon, in " fixing like
ness of youth, decorated with all kinds of ornaments, with a set of
pearly teeth, Devi, with a breast compact and full, gracefully bent at
three places, Destroyer of the Buffalo Demon, with ten arms as soft and
well rounded as the stalks of lotus, holding a trident on the right, a
sword and a discus from upwards, a sharp arrow, and a dart in the right
hand, a shield, a bent bow, a noose, a goad, and a bell or an axe. Under
her lies a headless Buffalo carcass, whence rises the demon with a sword
in hand, pierced in his heart by the Devi's trident, his lungs drawn out,
his body besmeared with blood, and eye-balls distended encircled by the
serpent noose, presenting a face made terrific by contracted eyes, brows,
and frowns, the noose with the forelocks of the demon held by Durga,
in her left hand, while the Devi's lion is described with a mouth tainted
with red, the right foot of the Goddess resting evenly on the back of the
lion, and the toe of the left foot a little higher on the shoulders of the
demon. Om serene-faced Goddess, subduer of the pride of Daityas and
Danavas I Om this representation of the Goddess is worshipped and
prayed [to ?] by the immortals. * * * Om contemplate the mother of
the world for the attainment of virtue, all wishes, and beautitude.
*asuri literally means pertaining to demons and the pungency of
the plant probably accounts for the name.
18
Colomdo College Sfiidies.
a post"; and the third and last, in slaying the foe. It will be
seen that it took jnst six days to complete the task, and at the
- end of that time the person was supposed to succumb.
This use of an image for such a purpose is to be found with
some modifications among all peoples who have practiced witch¬
craft. Among the Komans it was an image of wax slowly melted,
and in some parts of Europe to-day such an image is still used
stuck full of pins. The Ojibway Indian medicine-men make a
wooden image, put powders of some sort in a hole in the breast,
mutter imprecations over it, and pretend by this means to trans¬
fer diseases from one person to another. The negroes of Vir¬
ginia when suffering from rheumatism, or any malady that
draws up the limbs, go to or send after a " Conjur Doctor," who
is always a very old man. The "doctor" draws a picture of the
supposed witch, pins it to an oak tree, loads his carbine with
hair from the afflicted person's head, frog's legs, broken glass,
meal, pepper, salt, and divers other things, and finally shoots
the picture through the heart. This is supposed to kill the
witch and at the same time heal the sick person. There are
said to be cases in which the suspected witch has really died
from fright, knowing that the picture was intended for her. A
trick somewhat similar to those already given was even tried on
Henry VI, of England, and early in the present century on the
Nizam of the Deccan.
The fact that images have been so universally used in witch¬
craft practices is no more remarkable than the fact that all
nations have used them in religious worship. There is no dis¬
coverable connection between the Ojibway's wooden image and
the Hindu's effigy of dough, other than the mere fact that each
is the outcome of a desire to injure. Nature teaches both to
think of what is practically the same expedient.
The usuri rites do not end with this main, practice, but there
are several other similar ones with various objects, such as the
production of epilepsy, boils, loss of sense, family discord, fever,
eye-twitching, foolish or ridiculous action, a running behind the
Wifclicraft Among the Hindus.
19
witch's back by the person conjured, a running after senseless
people, invincibleness, success in love, power to charm with a
glance of the eye, also to obtain great treasure, to secure the
growing up of one's sons, to make a kingdom submissive, to
release A person from certain of the ill-effects already mentioned
as obtained by the rites, also from obstacles, ill-luck, and the
seeing of ominous portents. The MS. ends with the words:
' He is neither devoid of power nor destitute of children in
whose house the divine (the goddess) A s u r i is.'
It is a deep and interesting problem to determine the rela¬
tion between religion and superstition in its various manifesta¬
tions. The A s u r l-K a 1 p a shows that, in some cases at least,
witchcraft borrows the outward forms and symbols of religious
practices, though it must be admitted that in India, certainly,
the religious rites cannot claim to be much above the practices
copied from them in the matter of superstition. Witchcraft
also bears testimony to the universal belief of mankind in
powers outside of and above ourselves, though it tacitly denies
any divinity to them and seeks to conti-ol and use them for evil
ends.
It will perhaps be unnecessary to go further into a descrip¬
tion of the rites practiced by these charlatans of the East. Suf¬
fice it to say that, like the fortune-tellers and spiritualists of
America, their own personal gain enters largely into the account
in every case, and, furthermore, that they take advantage of the
universal belief of mankind in sojne supernatural power to
induce skeptics in religious matters to come to them and pay
them for gaining by magic blessings for their patrons, which
others get by prayers, or for producing evils to their fellows
which their religion would not countenance, save as a means to
do good for theii^ods or the Brahmans.
PROTECTION OF CONGRESSIONAL MINORITIES.
(Abstract of a Paper read before the Society.)
BY W. M. HALL.
I.
Abuse of the technical powers of majority and of minority
has not in any state legislature gone permanently beyond the
control of public opinion. But the House of Representatives at
Washington is notorious for frequent straining of such powers,
and there is little reason to expect a return to moderation with¬
out material changes in parliamentary law. Blame of one party
or the other is useless towards finding a remedy. The trouble
is old, and its marked increase in the present Congress is due
chiefly to the possession by one party of all three legislative ele¬
ments. Before, when the President or the Senate was hostile,
the majority in the House had less temptation to ride rough¬
shod, and the minority could leave the defense of its interests to
its allies beyond; repressive or obstructive abuses, when they
did occur, were often caused by the formation, on particular
measures not strictly partisan, of temporary majorities alike in
both houses, either in sympathy with the President or thinking
themselves strong enough to over-ride his veto. But now the
motives for parliamentary misbehavior on both sides are kept
permanently alive, and the descent is rapid.
When troublesome obstruction has become frequent, the
majority always does something to preserve its right to legis¬
late; but always hitherto by partial destruction of rights val¬
uable to the country—the minority rights to debate, to offer
amendments and have them put to vote, to make a conspicuous
Protection of Congressional Minorities. 21
protest, and sometimes to delay action till public opinion can be
roused. Unquestionably the majority right to legislate is still
more valuable. Is there no way to save it but by cutting down
the other set of rights?
The present agitation over breaking and counting quorums
is important only in so far as the minority has been driven from
other fields of dilatory action, and that subject may be neglected
if means can be found of restoring the more legitimate minority
rights.
II.
The demoralization of the House, extending through many
years, has been accomplished by a series of retaliations. Whether
it be held that the minority first abused its rights of debate or
of using parliamentary motions, (even dilatory use is fair, when
not too frequent), or that the majority began to shut off debate
and motions not meant to be dilatory, each development of ob¬
struction has been met by new repressive rules or by more mer¬
ciless use of old ones, and this in turn by more frequent exercise
of such powers of obstruction as remained. The result is that
the minority is disabled from giving the valuable services of a
minority; for the more doubtful the merits of the legislation in '
hand, the more eagerly the majority uses its silencing powers,
which are now great and effectual. We have the absurdity of a
system that makes an important right impossible when it is
most needed; and the absurdity will doubtless last as long as
the majority can decide, from day to day, how often and on
what subjects the minority can use its nominal privileges.
It is pointless to say that the minority deserves its punish¬
ment. The minority is not continuous. In each Congress it
suffers for the deeds of former minorities of both parties. It is
not the right of the minority as such, but the right of the whole
people to have tlje proper services of a minority, that needs pro¬
tection. It is good for the state that the minority should in
some principal cases (1) make a conspicuous protest, and rouse
public opinion for expression at the next election; or, (2) gain
22
Colorado College Studies.
time for contemporary opinion to work upon tlie majority and
perhaps check its action. It is no small matter to lose these
benefits. .Yet under the present system the incompatibility of
majority and minority rights is real, in a demoralized House.
There must be some limit of frequency to the obstructive powers
of the minority; and if the limit is applied by the majority, it
will be used too often, and most Sharply used at just the times
when it ought not to be used at all.
The root of the trouble is that the majority controls the
limit of frequency. If the control can be lodged elsewhere, the
minority can perhaps be restored to usefulness without recover¬
ing power for mischief. To give control to the Speaker is a mere
formal change, unless the speakership were made non-partisan.
To create a separate officer of the House, to decide when the
minority can properly ,use dilatory powers, is similarly imprac¬
ticable. But thei'e is another resource—the rules themselves.
If the minority can be given some effectual right, to be used only
a certain number of times, the limit is assured, and the minority
itself can be left to choose the critical moments for using the
right.
HI.
Suppose a rule of the House giving to six or seven members
of the minority each an absolute right to demand, twice during
his term, four hours' speaking for his own side, with the privi¬
lege of naming the members to use the time, while the Speaker
retains power to lengthen the debate by recognizing other mem¬
bers. A right to propose three amendments and require a vote
on them might well be added. The members to be armed with
these exceptional rights could be chosen by mere written' nomi¬
nation, (any twenty members naming one), or they could be
oflScers of the House elected under a minority-representation
rule of ballot. In either case the majority would have the same
privilege, in name, without motive to use it.
The minority would then have half a dozen responsible men,
chosen by their own caucus, able to secure in all, during the two
Protection of Congrexuonal Minoritiex.
23
years, about fifty hours of debate at the most useful times; an
allowance small enough to discourage waste of it, and large
enough to give opportunity for a conspicuous protest against a
dozen of the bills most objectionable to the minority. Each use
of such a power would itself call public attention to the protest.
At other times the majority would retain its present powers of
forcing business forward rapidly. The right to legislate and the
right to protest would no longer be incompatible.
It remains to provide means for saving the other function of
a minority, of forcing the majority sometimes to halt long
enough for adverse public opinion to act. Most of the bills
beaten in that way are really bad. Mere tiring out the majority
has no like claim to approval, and we need not regret seeing it
made difficult. But most of the true virtue of delay by obstruc¬
tion can be kept when general obstruction is abolished. Suppose,
again, that each member who carries the special right to claim
debate is further privileged once in his term to postpone arbi¬
trarily for two weeks the final vote on passage of a bill (or of a
resolution changing the rules or unseating a member); no repe¬
tition of the postponement admissible. The chance of an exer¬
cise of this right in the last two weeks of a session would put
no unjust hardship on the majority; they must bring partisan
measures to a vote, before the last fortnight, or obtain a two-
thirds vote to suspend the rules afterwards. The postponed
bill could meanwhile (by a slight change of Senate rules) be
considered by the Senate, go through conference committee, be
passed by the Senate, and return to the House to await its fate
on the postponed vote. But this is not an essential change;
the bill could be left absolutely suspended through the fort¬
night.
The minority could thus take a fortnight's grace on six or
seven important measures within two years, for the sake of
bringing outside plessure to bear on the majority; and would do
it without wasting any time of the House.
24
Colorado College Studies.
IV.
Such innovations need careful adjustment to the existing
rules of the House; but they seem to carry no inherent contra¬
diction such as has been developed into mischief by the work¬
ing of the present system. One considerable objection is visible:
the majority might divide into several short bills any measure
on which they expected resistance, or bring in several entire bills
with minor variations, hoping thus to exhaust rapidly the lim¬
ited minority privileges of debate and postponement. There is
perhaps no direct preventive of that trick, but in practice it
might disappoint the majority. They would be crowding their
own calendar and obstructing their own business; foreseeing
that, they would usually bring in these families of bills early in
the session, to insure their progress through committee. The
plan being thus exposed, the minority could choose one bill, the
worst of the group or the first one coming to a vote, and make
their stand on that. The privileged debate would, as protest,
be effectual in the public mind on the whole series, and if the
privileged postponement killed the bill selected for protest, the
same public opinion which drove the majority to retreat would
go far towards stopping the other fractional bills.
It is not claimed that these changes in the .rules would create
a perfect relation between majority and minority. Hut the
present system is full of abuses; abuses so connected that the
abatement of one aggravates another. A new principle is
needed, and apparently the only one that can loosen the dead¬
lock is one which gives the minority some privilege, far-reaching
when used, that can be used only a fixed number of times, the
times being chosen by the minority.
There is more reason to look for a good working device,
because the comparatively healthful condition of the Senate will
not last if the House becomes a quick-cutting tool of the major¬
ity. Obstruction will be habitually transferred to the Senate;
restraint of debate there will follow, and the downward course of
Protection of Congressional Minorities.
25
the House will be imitated. The process will doubtless be sus¬
pended when the President and majorities of both Houses are
not of the same party; it may even be reversed, and the House
itself brought back to moderation by some unexpected force of
public opinion. But it is not prudent to stake the future of
minority rights on such a chance.
2
PULSATIONS IN THE AORTIC ARCHES OF THE
EARTHWORM.
BY M. B. MANN.
Anyone working with the common earthworm has probably
noticed the extreme irritability of the animal at the touch of
the hand, due to the rapid evaporation from the delicate cuticle
surrounding the'worm. Observing also that the pulsations in
the aortic arches increased with the irritability, a few experi¬
ments were tried to note the effect of temperature upon the pul¬
sating arches of the common worm.
In the lowest animals the nutrient material resulting from
digestion is distributed in the same manner as in the cell.
The simplest form of a vascular system is found in the
Coelenterates, in which the digestive cavity occupies nearly
the entire space of the animal, and thus distributes the nutrient
material.
When a distinct alimentary tract is developed, the nutrient
fluid passes through the walls of the tract. Into the coelum, and
thus gives rise to the fluid, the blood. In this space the blood
circulates, the movement being effected chiefly by the muscular
actions of the body walls.
At a higher stage, a rudimentary central organ of circulation
appears, and the nutrient fluid is confined in special pulsating
-vascular trunks, by means of which the fluid is forced through
the system.
In the common earthworm a completely closed vascular
system is present, provided with pulsating trunks. A dorsal
longitudinal trunk, and a central longitudinal trunk can be dis¬
tinguished, the two being connected in the anterior end by
Pulsations in Aortic Arches of the Earthworm. 27
large pulsating aortic arches. These arches are sometimes
called " primitive hearts."
These experiments were performed with large strong worms
designated as A. B. C. The temperature was raised or lowered
as seen by the table with the following results:
1. Change of temperature causes great irritability.
2. After a short time the worm becomes accustomed to
change of temperature, and the aortic arches tend to revert to
the original beat.
See specimen A, temperature 19°; beats 14 16 14.
A, " 10°; " 8 11 8.
B, " 10"; " 8 10 9^.
3. The pulse beats with greater force at a low tempearture.
4. Tendency to same rate of beat in same temperature.
5. The upper limit is reached at 35°, when the pulsations
cease.
Table Showing Pulsations in the Aortic Arches of the
Earthworm.
Time.
Tempera¬
ture C.
Beats per minute.
A.
B.
C.
a. m.
10.40
19'
14
18
20
10.45
19°
16
16
14
10.52
19°
14
14
14
11.15
10°
8
8
10
11.20
10°
11
10
9
11.30
10°
8
9J
9J
11.45
5°
7
6
6
11.50
5°
7
6
6
11.55
5°
7
6
6
12.15
12°
11+
12
10
12.35
22°
26
22
19
12.50
29°
28
26
30
p. >r.
1.07
35°
0
0
0
DIALECTICAL STUDIES IN WEST VIRGINIA.
BY SYLVESTER PRIMER.
In studying the language or pronunciation of any section of
the country, it is necessary first of all to trace back the history
of the people inhabiting it to the earliest beginnings in order
to explain understandingly the dialectical peculiarities of its
grammar or pronunciation. I shall, therefore, preface my
remarks on the linguistical peculiarities of this region with a
brief sketch of its earliest settlement and later development.
The early history of Western Virginia, now known as West
Virginia, begins a century later than that of Eastern Virginia,
or Virginia proper. In 1710 Alexander Spotswood, a Scotch¬
man, was the deputy-governor of the Colony of Virginia. In
1716 he " gathered a party of the choice spirits of the Old
Dominion, and set out on an exploration of the country beyond
the Blue Ridge and Alleghanies, advancing as far as the fertile
fields of Kentucky." As far as we know, he was " the first
white man to enter the Great Valley, which was soon thereafter
occupied by large numbers of Scottish, and some German and
English settlers." In 1774 Virginia purchased from the Indians
the right to make settlements to the Ohio, and built a fort
where Pittsburg now stands. In 1752 Robert Dinwiddle, then
deputy-governor of Virginia, began active relations with the
great western country. " He encouraged trade and exploration
with this region, and the Virginia traders swarmed across the
mountains to traffic with the Indians, and there met with the
French, which finally led, as you remember, to the attack on
Fori Duquesne (now Pittsburg) and Braddock's defeat. At
about this time the Ohio Company of Virginia began to take
Dialectical Studies in West Virginia.
29
steps to settle the western region, and encouragement was given
both before and after the revolutionary war to settlers in this
region." In 1738 Augusta was the frontier county, and then
extended westward indefinitely. To the north lie Bockingham,
Shenandoah and Frederick counties. Nearly all this region was
settled by Germans and Swedes. "A Swedish congregation
was here collected, and the Bev. Peter Muhlenburg, son of the
Bev. Mr. Muhlenburg, father of the Lutheran Church in
America, was sent to take charge of it." To the south lie
Bockbridge, Botetourt and Montgomery counties. Botetourt
became in 1769 the western frontier. From here the emigrants
pushed forward to the westward, and soon settled the whole of
what is now West Virginia.
History tells us that the Presbyterians were first in this field,
and the fact that the people are of Scotch and Scotch-Irish
descent would lead to the same conclusion. But it must not be
forgotten that a greater part of the population of West Virginia
were emigrants from Maryland and Virginia. A comparison of
the names also will indicate in a general way the national charac¬
teristics of the inhabitants, and show whether there has been
an intermixture of outside.elements with the original settlers.
However, too great stress should not be placed on mere names,
as they might not always show the true nationality of the section
from which their bearers came. Yet they are not to be dis¬
carded altogether, but must be taken into account in dialectical
studies. They will show approximately whether the population
has remained pure from the earliest times. On examining the
names of the vestrymen of the earliest Episcopalian churches
of this region, my only source of information, 1 find among the
settlers from Eastern Virginia such names as Ballenger, Maury,
Burton, Scott, Bucker, Godwin, Taliafero, Cabell, etc. Among
the Scotch and Sicotch-lrish names can be mentioned Bal-
maire, Quarrier, Dunlap, etc., while Bittenger, Swearingen,
Muhlenburg, show a sprinkling of German and Swedish names.
The names of the present day afford the same testimony and
30
Colorado College Studies.
show that the earliest settler^ are fairly well represented by the
present inhabitants. I am well aware, as above remarked, that
this is not always a safe guide, but may, like tradition, some¬
times mislead; still, in lieu of a better one it renders tolerably
efficient service.
In the earlier days of these settlements the educational advan¬
tages were naturally slight, but later the conditions for educa¬
tion were about the same as those described in my article on
the Pronunciation of Fredericksburg, Va., printed in the Publi¬
cations of the Modern Language Association of Ameiuca, Vol. 5,
p. 188ff. In the same article (pp. 192-195) I have compiled two
Vowel Tables, one representing the vowel sounds of the Vir¬
ginia English of the seventeenth century, and the other the
vowel sounds of to-day. In the present article I shall con¬
stantly refer to them.
I will here begin with the vowel a as heard in father (Sweet's
mid-back-wide).* Here, as in Fredericksburg, Va., we find the
clearer, lighter sound of a as in calm, psalm, palm, half, etc.
The other sound of these words (?'. e., kcecem, soeoem, poeoem,
hcecef, etc., that is. Sweet's low-front-wide) is heard, though less
frequently than in Fredericksburg, Va., or in Charleston, S. C.
This sound of a in father (mid-back-wide) is also very common
in words like ask, demand, pass, trespass, etc., though the ten¬
dency to the palatal a is strong. The two words ant and aunt
are both generally pronounced (cent, that is, low-front-wide),
though the latter is often pronounced (aant, that is, mid-back-
wide). The same remark applies to words like gaunt, haunt,
jatint, etc., where Sweet's low-front-wide ( = a in man) is
commonly heard, thus (goeoent, Hoeoent, Dzhceoent, etc). Oc¬
casionally one hears the mid-back-wide {—a in father)-, that is
phonetically represented (gaant, Haant, Dzhaant), but I have
never heard Sweet's low-back-narrow-round (= a in law,
* The signs of Sweet's Primer of Phonetics are used in this article,
except in quotations.
Dialectical Studies in West Virginia.
31
gAAnt, HAAnt, DzhAAnt, etc.) Among all classes here, and
especially among the uneducated, the mid-back-wide sound of a
is retained in a large class of words where it either reflects the
older pronunciation or shows the influence of the negro ele¬
ment. The negro is very fond of this a-sound, but I am in
doubt whether it is natural to him or whether he may not have
acquired it in early times from the whites themselves and re¬
tained it pure and uninfluenced by the change which this vowel
has undergone in the progress of the language, just as the Irish
have retained the older pronunciation of English. According to
Elllis, E. E. P., this was the usual sound of the vowel a in the
sixteenth century. In this list we flnd words like clear, pair,
there, where, fair, learn, prepare, queer, bear, square, were,
rearguard, search, swear, etc., in all of which the mid-
back-wide is heard (klaar, paar, dhaar, whaar, etc.); we sel¬
dom hear the low-front-narrow (dhser, etc.) as in Charleston,
S. C., but more usually the low-front-wide (= a in man).
I am inclined to think that this sound is midway between
the low-front-wide and the low-front-narrow. The negro
pronunciation of here is (^Hj'ar). Among the white popu¬
lation two pronunciations obtain; both ('ji'r) and ('ja'r) are
common.
Under Sweet's mid-front-wide (our e in mei, either long or
short) we must class one peculiarity not yet noticed elsewhere,
though found in England, viz., the pronunciation of the word
make as mek, that is, mid-front-wide instead of mid-front-
narrow. In the 17th century we find the same sound in Eng¬
land in the words main (meen), major (meedzhar), mayor
(meer), naked (necked), nature (neetwr). Dryden has pains of
hell (peenz of Hel) and (mee) for may. Garth has distress
rhyming with place (plees). In the 16th century this word
make was pronounced (maak), that is. Sweet's mid-back-wide
32 Colorado College Studies.
as we see in Shakespeare's Henry VIII., in the speech of Car¬
dinal Woolsey to Cromwell:
Neglect him not; make use now and provide
For thine own future safety.
which according to Ellis, E. E. P., 3,991, is to be pronounced
Neglekt Him not; maak yys nau and provaid
For dhain oouii fyytyyr saafti.
The Anglo-Saxon form is macian where this vowel has the
short sound of a in father, that is, Sweet's mid-back-wide. In
Mid. Eng. the form is still makien and retains this mid-back-
wide sound. But in 1766 Buchanan in his conjectured pronun¬
ciation of Shakespeare has: " Meed tu Hi'z m/stri's aibrau, and
Kenrick, 1773, giving the pronunciation of the same passage
has: " Meed too Hiz mistris aibrau." Both agree in the pro¬
nunciation of (meed) for made, so that this mid-front-wide
sound of a in the verb make must have obtained in England to
some extent in the 18th century. Benjamin Franklin, also, in
his remarks on pronunciation in 1768 indicates the pronuncia¬
tion of makes as (meeks). I am also informed that in at least
two counties of England, Lancashire and Derby, the pronun¬
ciation (meek) is still heard.
The character e in the word well has a sound between Sweet's
mid-back-wide {father) and low-front-wide {man), but inclin¬
ing to the latter (w»l), possibly Sweet's low-back-wide, Swed.
mat. The word ancient belongs also to this class as it is here
often pronounced (anshent) Sweet's mid-back-wide again. In
addition to the two pronunciations (agen, agenst) and (ageen,
ageenst) we find the pronunciation (agm, aginst), though only
as vulgarisms. Foment {fornenst, pr. frnent) may have led to
the pronunciation of (bi-jent).
Sweet's mid-back-narrow {but) is very common to this
region. It is what Sweet and Ellis call the American sound of
the u in but, not the English. Here belong words like took,
look, cook, shook, book{^),put, and others, all of which have nearly
the sound of our u in but. A sound between Sweet's mid-mixed-
Dialectical Studies in West Virginia.
33
■wide-round (6, Fr. homme) and his high-mixed-wide-round (u.
Swed. Mpp) is heard in could, would, should; in cool, good,
school, who, though preceded by the i-umschlag (kittd, wiifd,
shiud; kiwi, ski^ll, Hm). I hardly know whether this sound is
to be attributed to the Scotch element among the early settlers
or not. It certainly comes very near the Scotch sound as heard
in guide (girtd). It is, however, possible that it developed on
this soil independently of the Scotch influence. This pronun¬
ciation is also peculiar to Fredericksburg, Va., and is heard in
various places in the state of South Carolina. In the Upland
region we have also a Scotch influence to some extent, so that
even here it .may be due to this element. I have noticed it more¬
over in other localities in the pronunciation of individual people.
This sound of u in hut is often heard in the pronunciation of
careless, thus (karles). Care itself is often pronounced either
(ktr) but more often however (kear). Here belongs also that
peculiar pronunciation of room (riztm) and tomh in rhyme with
perfume (tium, parfiwm). .
In studying the pronunciation of Fredericksburg, Va., I
noticed two cases of the short (i) in the words (hill) and (mill).
In West Virginia I found another example of the same sound
in an individual pronunciation of the preposition In (iin). The
word ear is often pronounced (jiir or even (jar). Mischief is
accented on the ultima and pronounced (mistshiif). The past
participle of hear is pronounced either (Hiirn or Harn; or
Hiird -or Hard), according to the form used. The sound (i)
and (e) are often interchangeable, as (led) for lid, (red) for
rid, (ef) for if-, (git) for get, (jit) for yet, (jistardei) for yester¬
day, (kitl) for kettle. To these we may add (dzhinereshan) for
generation, (sperit) for spirit, (resen'kshan) for reserection. The
word muskmelon is here often pronounced (maskmiljan), which
pronunciation gofts back as far as 1685; for Cooper, in his list of
words like and unlike, gives melon, melo, million, 1,000,000 sive
centum myriades, which would indicate that the two words were
nearly alike in sound. In miracle the i-sound often follows the
34
Colorado College Studies.
analogy of vowels before r and we hear not infrequently
(marikl).
I feel convinced that we hear the open o-sound (Sweet's mid-
mixed-wide-round=0, Fr. encore) in the word poor (pr. poor),
and we also hear the long o-sound (Sweet's mid-back-narrow-
round=o, Germ, so; pr. poor). The former is the same sound
we often hear in the last syllable of/eZZoio and/oZZomj, though
the latter is the more common sound. The two words horn and
borne are both pronounced alike (b£)rn). Forward is frequently
pronounced (farard). The words only and onhilch (unhitch)
belong here, as they are often pronounced (dn-li, dn-hitsh).
I can here repeat my remarks on the diphthongs in my
article on the pronunciation of Fredericksburg, Va. "The
sound (au, as in German Haus) is heard among a select few in
house, now, etc., though the usual pronunciation is here (eu),
never (su). This latter diphthong (eu) is long (eeu) in town,
coto and some other words, and short (eu) in most words, as
house, out, about, south, pound, etc. Often (EEe) is heard in¬
stead of long (eeu), and (Ee) instead of short (eu). The diph¬
thong (iu) is very common and the first element is often length¬
ened (iiu). Sometimes, however, the vanish is prolonged (iu").
Instead of (iu), (iu) is often heard, especially among the lower
classes. Fruit may be classed here also, or the sound often
comes nearer the Swedish u in hus (frUt), or (yw). The same
sound seems to be peculiar to people from the middle and upper
parts of South Carolina." The diphthong (ai) is often changed
to (oi), as in title (toitl). On the other hand (oi) often be¬
comes (ai), as boil (bail), joinZ (dzhaint), etc., but this is a vul¬
garism common to all parts of the country. The word ewe
(jiu) has frequently the pronunciation (joo), a pronunciation
very common in Western New York. We also find (rai-at) for
(rait), that is, right.
The consonants offer a few peculiarities. The h is often fol¬
lowed by the J-sound in the word here (Hjeer); in this case the
h frequently becomes silent, or rather a mere breathing ('jeer).
Dialectical Studies in West Virginia.
35
W is exchanged for v in very (weri) and a few other words^
The r is heard here more than in other parts of Virginia, but is
often silent when final. We occasionally hear (kjart, gjardn,.
etc.), but not so commonly as in Virginia proper or in Charles¬
ton, S. C. After s a f is often added, as close, pr. clost. The gr
disappears in words like length, strength, etc., which are pro¬
nounced (lenth and strenth, etc.). The t between the s and I of
words like apostle, epistle, etc., is sounded.
The accent of words is often changed, either as a general
rule or by individuals. Idea frequently has the accent on the
first syllable (aidf, or aidie). Mischief often transfers the
accent to the last syllable (mistschiif), though this is considered
a vulgarism. Difficulty sometimes has the accent on the ante¬
penult (di-f/k-al-ti). Trespasses sometimes takes the accent on
the penultimate (tres-paa-sez). Contrary, when it means per¬
verse, froward, wayward, always has the accent on the penulti¬
mate (k^ntre^ri). Elizabeth often has the principal accent
on the ultima (IhzEb^TH). Gethsemane is often accented
(Geth-se-m e6n).
Turning to the grammatical peculiarities we find the great¬
est variety in the verb. The tendency here is to form peculiar
past tenses and past participles. Often one is exchanged for
the other without any apparent reason. This is especially the-
case with the irregular verbs. The following list contains all
those which I have observed:
1. Blow
blowd
blowd
2. Climb
climm or clomb
ciimm or clomb
3. Fight
fit
fit
4. Freeze
frozed
frozed
5. Hear
(Hiird), (Hiirn), (Harn) (Hiird; heard
6. Heat
het
het
7. Help
^ helped (holp, pr. Hop)
helped (holp)
8. Know
knowd
knowd
9. Hide
rid
rid
10. See
saw (seen, see, seed)
seen (seed, saw)
11. Take
took (taken)
taken (took)
36 Colorado College Studies.
I find also a few lexicographical peculiarities which I shall
give promiscuously, as it is not possible to arrange them in any
definite order. Reverent is used in the sense of genuine,
thorough, as a reverent scolding, that is a thorough scolding.
Satisfactual is a vulgarism for satisfactory. Shoot is very com¬
mon for shot, as " he made a good shoot." Arter for after is
<5ommon all over the land. Bold is used in the sense of strong,
vigorous, as a bold spring is one whose waters bubble up
strongly. A bunch of cattle, is the only proper expression here
in the West, but I never heard it in the East except in West
Virginia. Webster's International, and the other dictionaries
■do not give this meaning for the word, though the Century gives
<i bunch of ducks. May not this meaning have started in West
Virginia and passed to the West? Gradjate and sosation are
vulgarisms.
An amusing popular etymology is found in the name of one
■of the valleys on Indian Greek. It is known as the Tuckahoe
valley, and takes its name from the Indian tribe of that name,
or it is at least an Indian name. The people living in this
-valley are of the lowest class, and have a peculiar dialect of
which I have already noticed the.most prominent features. Not
being able to explain the word Tuckahoe they have based the
derivation on the peculiar pronunciation of the past participle
of take (took, p. tak), and ahoe is then made to mean a hoe,
"he took a hoe." To this derivation the following legend has
been attached; An inhabitant'*of this valley once became so poor
that he was at last reduced to stealing, and he took a hoe, that is,
stole a hoe. This will compare favorably with the English cor¬
ruption of the name of the ship Hirondelle into Iron Devil, or
the route du poi into Rotten Roto, or Bellerophon into Bidly
Ruffian, etc.
Kittering means toppling, afore stands for before, trcoisits
means, not transits of the planets, but transient guests at a
hotel. One minister, a hardshell baptist, or Ironsides as they
■call this sect there, spoke of the texes from which he preached
^ Dialectical Studies in West Virginia. 37
his sermon. I need not add that he was from Tuckahoe valley.
Slick is used in the sense of slippery, heegum is used for hee-
hive. The Century Dictionary gives the word; it was at first
the body of the gum tree hollowed out and used for bees. A
larger section, hollowed out in the same way, is used for a grain
receptacle, and is called a gum. A band of music is called
musicioners. In Fredericksburg, Va., I found this summer the
word burr meaning gherkin, and have not yet been able to dis¬
cover any explanation of it. The name may have some connec¬
tion with burr-weed, though I doubt it. Opiionary is an indi¬
vidualism for optioned, though having the force of capricious.
Pert (pr. piirt) is used in the sense of well, as I am feeling
right pert to-day.
The region is full of peculiar expressions, and the careful
collector would be well repaid for his trouble. Like the
proverbs, the quaint sayings, the peculiar expressions of a
nation form an interesting chapter in its history, and give a
better insight into the distinguishing characteristics of a people
than long years of its civil history. Often thoughts of ages are
crystallized in such expressions and the study of intellectual
growth and civilization of a nation cannot be pursued more
effectively than by collecting and classifying its apothegms.
But it is not my intention to enter so deeply into the subject,
as I have given most of my time to the peculiarities of pronun¬
ciation and grammar. Besides, it would require years of study
to collect all these expressions and put them in their proper
order. I shall here select only a few of the most amusing and
peculiar ones to show you what a rich field for such researches
this section of the country affords.
A right smart little bit is extremely common, and right smart
seemingly may find a place beside it. I had laid out to go to the
Dunkards to-mr^ht is a not infrequent expression; of the same
signification are to go to do and to aim to do. Let on is common
nearly in the whole country; and so is to get shet {shut) of. I
jeel like she did not do it meaning I think she did not do it is
38
Colorado College Studies.
often heard among all classes of people. Some of the more
amusing ones are: I feel rather dauncy meaning I feel rather
poorly. Again we have a popular derivation for dauncy, which
is rather more expressive than elegant. I have been told
soberly by different ones that it is a contraction of damn sick.
TJie dictionaries give no information on the subject. As an
explanation of this word I would suggest, though with great
hesitation, the French word dancettS, or the more common form
is danchS {denchS), from which we have in English the two
words dancettS and dancy. The great trouble is with the mean¬
ing. Both words are terms of heraldry, descriptive of escutcheons
having the edge or outline broken into large and wide zigzags.
The real meaning of the word is indented, and it probably stands
for deni6. Possibly the idea of being broken or notched like the
teeth of a saw may have been applied figuratively to physical
nature and would certainly have as much sense as the broke bone
ever so common in malarial districts, and so dreaded. The
most amusing expressions, however, were those heard in an
Ironside sermon. But it would be impossible to reproduce
them as they would lose their flavor if not delivered by the
minister in person.
Often these expressions are of grammatical nature and
deserve a careful study. Here are several of that character:
Would you rather have this as thati though I have heard as
used for that after the conjunction than in various parts of the
country. A good old construction is retained in the following:
With the blood a-runnin' down his side. This corresponds to,
he lay a-dying, etc. Another (bible) construction is retained in
this: They looked for to see him die every day. For to instead
of to is now obsolete. The double comparative is not infrequent
here. I noted more pleasanter on several occasions. In ex¬
pressions of weather I find the following in my.note-book: To
fair off meaning to clear off; to have a cloud meaning to have a
■shower.
THE STUDY OF DIOPHANTINE ANALYSIS IN THE
UNITED STATES.
By Floeian Cajoei.
I. Introduction.
The term "number " was used by the Greeks in a restricted
sense. With early mathematicians, as the Pythagoreans, it was
never used except for integers. With them even unity was no
number; a collection of units only was designated by that name.
Fractions were looked upon as merely ratios of numbers. Later
Greek authors, particularly Diophantus, enlarged the use of the
term so as to include fractional numbers; but never were irra¬
tionals classified as numbers by any Greek mathematician.
The oldest extant work on algebra is the one of Diophantus.
He took pains to exclude from his book the methods and con¬
ceptions of geometry which before his time had been extended
by the Greeks even to arithmetic. Since irrational quantities
were not looked upon by the Greeks as numbers and since, to
their minds, they represented only lines, surfaces, and solids of
definite dimensions, they could not be admitted into the algebra
of Diophantus. According to him, algebra could be built up
independently of geometry only by the exclusion of irrational
solutions. Hence arose the condition, imposed by him, that
solutions should be given in numbers.
The term " Diophantine Analysis " is sometimes used in a
wrong sense. An equation, aa; hy = c, in which only integral
values of x and y'are to be found, is frequently called "Dio¬
phantine." But the solution of this equation was unknown to
Diophantus; nor did he ever propose to himself such a problem.
He always imposed the condition that the results be rational.
40
Colorado College Studies.
but never that they be exclusively integral. The distinction
between the modern Theory of Numbers and Diophantine
Analysis has not been observed by American and many.
European writers; and we find it therefore most convenient, in
this article, not to insist upon this distinction between the two.
The leading characteristics of Diophantus's solutions of
indeterminate problems is the startling ingenuity and dexterity
displayed, the lack of general methods, and the failure to detect
multiple values in the answers.
II. Work in the United States.
The study of Diophantine Analysis was introduced into the
United States by Eobert Adrain, a mathematician whose work
in one department of mathematics has not been sufiiciently
appreciated. He contributed to the Mathematical Corre¬
spondent, the earliest American journal of mathematics, started
in 1804 in New York city, an essay, entitled, " A View of the
Diophantine Algebra," in which he gives a general discussion
of principles. He contributed later on the same subject to the
Ancdyst, of which he himself was editor.
One of Professor Adrain's pupils, William Lenhart (died in
1840 at Frederick, Maryland), devoted much of his time, year
after year, to the study of Diophantine Analysis. He was a
cripple, and pursued mathematics for pastime. Frequent con¬
tributions were made by him to the Mathematical Diary and to
the Mcdhemcdical Miscellany. In the latter were published
"Useful Tables Relating to Cube Numbers." The editor states
that besides these tables, the manuscript compiled by Mr. Len¬
hart with so much labor and care included a table containing a
variety of numbers between 1 and 100,000 and the roots, not
exceeding two places of figures, of two cubes, to whose differ¬
ence the numbers are respectively equal; together with another
table, no less curious, exhibiting the roots of three cubes to
satisfy the indeterminate equation, = A, for all
values of A from 1 to 50 inclusive. These enabled him to solve
Study of Diophantine Analysis in the United States. 41
many difficult problems relating to cube numbers. Thus, it
can be found that 4 is composed of three cubes whose roots
are greater than unity. This gives an answer at once to the old
puzzle, "to divide unity into three such positive parts that,
if each part be increased by unity, the sums shall be three
rational cubes." " And if the division of unity," says David
Engel in Our Sclioolday Visitor, 1871, p. 36, "into three such
parts as above stated has beaten the mathematicians of two
continents, what would be the effect of dividing unity into 12
such parts, which (by means,of these rules) can be done with
about as much ease and facility in one case as in the other?"
Mr. C. Gill, the editor of the Mathematical Miscellany, who
furnished an abstract of Lenhart's speculations, points out the
great defect in them, which robs them of any scientific value.
It lies in their " tentative character." As it nowhere appears
that a given number A, is necessarily capable of being decom¬
posed into three cubes, in the manner proposed, " there is
nothing to insure us that, by successive trials, we shall at last,
arrive at a number which is the sum of two cubes, much less
that we shall arrive at one already tabulated."
Some attention to our subject was paid by John D. Williams,,
the author of works on elementary mathematics. In 1828 he
started the 3Iathematical Companion as a rival, it would seem,
to the 3Iathematical Diary. Williams had many opponents,
and a bitter contest was carried on between the two parties.
He finally issued his 14 famous " challenge problems,''
directed against all the mathematicians in America, excepting
three.* The fact that all 14 problems were on Diophantine
Analysis tends to show to what great extent that subject was
engrossing the attention of a certain class of mathematicians
*■ To illustrate the bitt*iiess with which the contest was carried on, we quote from a
communication to a newspaper made by Williams in 1832 a passage which has reference
to one of his rivals. " I beg leave to state that I received from this gentleman correct
solutions to questions 1,2,3,4, 5,10,13 and 14. This, I suppose, is about his neplus ultra
—beyond which I defy him to advance ' till riper age shall with maturer force burnish his
mind.'"
4
42
Colorado College Studies.
here. In the newspaper communication referred to in the foot¬
note, the first problem and its answer are stated as follows:
+ if = d' — + id^ = □
and — vf — — if = □
Answer, If a = 7585, then x = 7400. y =1665. z = 6273,
w = 4264.
The answers are, apparently, expected to be in integers. If
a general solution is to be given, then the above problem is not
so very easy, but Diophantists care but little for general solu¬
tions. Assuming a particular number for a and then finding
one set of values for an answer gives them perfect satisfaction
How many other values, if any, really exist, and what they are,
does not concern them much.
Among the writers in the Mathematical Companion inter¬
ested in Diophantine Analysis, appear the names of Dr.
O'Eiordon, AVm. Wright, T. Beverly, and Cunliffe.
One of the .best Diophantine scholars in this country was
Charles Gill, editor of the Mathematical Miscellany and pro¬
fessor ofj mathematics at the St. Paul's Collegiate Institute at
Flushing, Long Island. He published, in 1848, a book of 90
pages, entitled, "Application of the Angular Analysis to the
solution of Indeterminate Problems of the Second Degree." *
This is a charming little work. Of all publications on Indeter¬
minate Analysis that we have seen, this least deserves the
adverse criticisms we shall make on the work done in this
country, taken as a whole. Here an effort is made to introduce
method and to exhibit general solutions. The novelty of the
book consists in the application of the notation of Trigonometry
to Diophantine Analysis. So far as we know Prof. Gill is the
first one to make this application. If the sine and cosine of
an angle can be expressed as rational numbers, we may assume
:sin A = ^ and cos A=^5—^, and then all other functions
m'^+m m''-)-m
* A copy of this now rare book was lent the writer by Dr. Artemas Martin, of
Washington.
Shidy of Diophantine Analysis in the tfnited States. 43
can likewise be represented by rational numbers. He then
includes all equations for the six trigonometric functions in the
symbolical form A=^( .5^ ), — being called the "root of the
V n ^ n
function." He then solves the three problems: (1) To find the
root of the function in terms of the angle; given the roots of
the function, (2) to find the root of their sum and (3) of their
difference. This occupies eleven pages in the book. The rest
of the work is devoted to the application of this notation to
indeterminate problems and to geometry. The thirtieth and
last problem on the former subject is "To find n square numbers
such that the sum of every n—1 of them may be square num¬
bers." As an example of the geometric problems solved we
quote this: "To find the sides of right angled triangles in rational
numbers, which have equal areas."
The solution of a few difficult Diophantine problems was
communicated to Silliman^s American Journal of Science by
Theodore Strong, Professor at Eutgers College (died 1869). He
was one of the few men in this country who possessed some
knowledge of Gaussian methods in the theory of numbers,
which he employed in published articles, once or twice.
All the mathematical periodicals, except two of our present
journals which are devoted to advanced mathematics exclusively,
have given a good share of their space to Diophantine analysis.
Men of a mathematical turn of mind liked to exercise their
ingenuity in this field. Eev. A. D. Wheeler discoursed " On
the Diophantine Analysis" in the Mathematical Monthly of
August, 1861. Professor George E. Perkins wrote on it for the
Analyst of J. E. Hendricks. Dr. David S. Hart, of Stonington,
Conn., was a faithful follower of Diophantus. He wrote an
outline history of indeterminate analysis for the Mathematical
Magazine (Vol. I, No. 10), also articles entitled "Square Numbers
Whose Sum is a Square" (Vol. I, No. 10), "Diophantine Solu¬
tions" (Vol. 1, No. 3), "Consecutive Square Numbers Whose
Sum is a Square" (Vol. I, No. 8),"Cube Numbers whose Sum is
44
Colorado College Sfiidies.
a Cube" (Vol. I, No. 11). In Our Schooldag Visitor of 1871 is
an article on our topic. In the Mathematical Visitor he solved
Diophantine problems numbered 21, 65, 112, 129, 197. Other
solutions of his are given in Dr. Matteson's collection. The
Mathematical Visitor contains Diophantine solutions by Asher
B. Evans (114), Eev. U. Jesse Knisely (123), Reuben Davis
(126,129), Josiah H. Drummond (114), George Eastwood (177),
Sylvester Robins (179), Samuel Roberts (185), William
Hoover (191).
In Vol. I, No. 5, of the Mathematical Magazine Dr. Martin
quotes from sheets bound in a copy of J. R. Young's algebra,
once owned by Abij ih McClean, of New Lisbon, Ohio, some
curious properties of numbers. Among other cariosities are
given 27 numbers, all squares, composed of the nine digits,
each digit being used once and but once. Dr. James
Matteson was able, however, to add another number to the
27 of McCIean, possessing the above property. In dis¬
covering these numbers Barlow's Table of Square Numbers
was made use of. We are told that in 1885 an anonymous
writer in the Stanford Sentinel challenged the entire faculty of
Yale College to arrange the nine digits in such order as to form
a perfect square. It will be seen that this is the same problem
as the one given by McClean. A. D. Stanley, who then occu¬
pied the mathematical chair at Yale, a few days after the chal¬
lenge, published one solution and called upon the proposer to
produce other answers, as there was more than one. The
opponent made an evasive reply, stating that there were nine
solutions, but Stanley found twenty-eight different ones.
Neat solutions of Diophantine questions were published by
Dr. Artemas Martin. In 1875 and '76 he communicated a series
of sixteen articles to the Normal 2Ionihlyj in 1874 he wrote for
the Analyst on the difficult problem to divide unity in three
such parts that if each part be increased by unity the sum shall
be three rational cubes. Solutions of the same problem were
given by William Lenhart, by Reuben Davis, of Bradford, 111.,
Study of Diophayitine Analysis in the United States. 45
in the Mathmatical Visitor of 1880, and by A. L. Foot in the
School Messenger (now Mathmatical Messenger), Vol. Ill, No. 8.
Dr. Martin published solutions of his own also in the Mathmatical
Visitor. In 1887 he read before the Philosophical Society of
Washington a paper "On iith Power Numbers Whose Sum is
an nth Power."
In the Mathmatical Messenger published by G. H. Harvill,
of Louisiana, indeterminate problems are solved by A. L.
Foote, B. F. Finkle, B. F. Burleson. In the School Visitor,
published by John S. Koyer, we have seen contributions of B.
F. Fiukel and D. H. Davison.
A most interesting "Collection of Diophantine Problems
with Solutions, compiled by James Matteson, M. D., of De
Kalb Centre, Illinois," and published by Dr. Martin, 1888,
exhibits the results of Diophantine studies in this country at
their most advanced stage. The solutions of probloms 1 and 4
in this collection are by the late Abijah McClean, of New Lisbon,
Ohio; 5, 7, 9, 22, and 24 are from the pen of Dr. D. S. Hart;
6, 8, and 12 are by Dr. Matteson. The remaining solutions are
chiefly the work of Reuben Davis, of Clifton, Kansas. A small
pamphlet giving "A Discussion of the equation V,
when h, p, h are Integer Numbers," by Josiah Scott, was pub¬
lished at Bucyrus, Ohio, in 1871.
Diophantine problems were such a favorits study that at one
time they found their way into some of our school-books. This
may have been done in imitation of English writers, such as
Bonnycastle, whose little algebra was republished in this coun¬
try. Charles W. Hackley, in his " Treatise on Algebra," 1846,
gives eleven pages to Diophantine Analysis and thirty-five
pages to the Theory of Numbers in which he introdnces the
Gaussian notation* for the treatment of congruent numbers.
Enoch Lewis has a chapter on indeterminate analysis in his
algebra. The key to Ray's Algebra devotes some space to our
topic.
46 Colorado College Studies.
III. Estimate of the Work Done.
In the examination of the more diflficult Diophantine prob¬
lems solved by the men above referred to, we are often struck
by the great ingenuity displayed. In following the intricate
paths, we often wonder how the patience of the solver endured
to accomplish it. We are sometimes tempted to exclaim,
" Here we have indeed a true disciple of Diophantus," or " This
solution is after Diophantus's own heart." Some of the work is,
in point of difficulty, in advance of anything we have of Dio¬
phantus himself. And indeed it ought to be, for the ancient
algebraist worked under the enormous disadvantage of having
but few algebraical symbols and of not possessing the Arabic
notation of numbers. And yet, our ingenious solutions, however
dazzling, fail to satisfy us. They fail to teach us general
methods. The solution of one problem may give us no clue what¬
ever as to how the next one should be solved. Our Diophantists
are dexterous and indefatigable; they lead us by intricate and
laborious processes to an answer which may consist of rational
fractions with numerators and denominators of 30 to 50 digits,
or which may have integral values of upward to 150 digits.
But little or no effort is made to determine whether all possible
solutions have .been found, and to show how the remaining
answer can be obtained. The problems are, after all, treated
very superficially. Their inner secrets remain, to a great extent,
unraveled. The lack of general methods by which full and
complete solutions can be obtained, renders the work done of
little or no scientfic value. That the discovery of powerful
methods is more valuable than the obtaining of an answer to
some particular problem will be conceded by all. To illustrate:
When Nathaniel Bowditch, in the Analyst of Robert Adrain,
succeeded in adjusting discordant observations obtained from
a survey of a certain piece of land, so as to obtain the most
probable values in that particular case, he displayed cleverness;
but when Robert Adrain worked out a general method by which
Study of Diophantine Analysis in the Uhited States. 47
all sucli problems could be solved, and thus elaborated the all-
important law of the Probability of Errors,—he did work of
immeasurably greater value to science. When the future histo¬
rian writes the history of indeterminate analysis, we fear that
work in Diophantine Analysis done in this country will count
for little or nothing. It is to be regretted that American math¬
ematicians did not fall in line with leading foreigners and follow
the path marked out by the illustrious Gauss in the Theory of
Numbers. The modern theory of numbers is a field, wonder¬
fully beautiful, and adorned by most elegant and powerful
general methods. In a few mathematical centres of the United
States the theory of numbers is now taught, but original con¬
tributions are still rare. In the past. Professors Benjamin
Peirce and Theodore Strong are the only ones who by their
publications in journals exhibited a knowledge of Gaussian
methods. A quotation from an article by Dr. J. W. L. Glaisher
{Nature, September 11, 1890) will apply to the United States
much more forcibly than to England: "It is much to be
regretted that this great theory, perhaps the greatest and most
perfect of all the mathematical theories, should have been
so little cultivated in this country. * * * From the mo¬
ment that Gauss, in his wonderful treatise of 1801, laid down
the true lines of the theory, it entered upon a new day, and
no one is likely to he able to do useful work in any part of the
subject who is unacquainted with the principles and conceptions
with which he endowed it."
THE ELLIPTIC FUNCTIONS DEFINED INDEPEND¬
ENTLY OF THE CALCULUS
BY FEANE H. LOUD.
Among the minor works of the eminent mathematician, C. G.
J. Jacobi, is one containing a geometrical construction for the
addition-theorem of elliptic integrals,—a construction, as the
author remarks, which is not without advantage over that given
by Tiagrange by the use of the spherical triangle. The sugges¬
tion of Jacobi has been followed by several writers of text¬
books upon the elliptic functions: it appears, e. g., in brief on
pp. 28 and 29 of Cayley's "Elementary Treatise," and is much
more fully handled by Durfege, "Theorie der Elliptischen
Functione^i," pp. 168-190. The object which I propose at
present is to apply the Jacobian construction to a still more
primary use; viz., to produce from it a definition of the elliptic
functions which shall be independent of differentiation and
integration, and being based on the methods of elementary
mathematics alone, or those anterior to the calculus, shall enable
the student to form a preliminary conception of the elliptic
functions analogous to that which he acquires of the sine,
cosine, etc., in elementary trigonometry.
The memoir of Jacobi here cited appeared in the third
volume of Crelle's Journal; and is to be found in his collected
works, (Berlin, 1881,) on pp. 277-293. It bears the date of April
1st, 1828, and is entitled, "Upon the Application of the Elliptic
Transcendents to a known Problem of Elementary Geometry;
viz., to find the Relation between the Radii and the Distance
between the Centers of two Circles, one of which is inscribed in
an Irregular Polygon, and the other is circumscribed about the
The Elliptic Functions Defined.
49
same." Among the historical references which it contains to re¬
searches bearing upon this problem, there are several to theorems
of Poncelet, which, as Jacobi shows, may easily be demonstrated
by the use of elliptic functions. In reversing the procedure of
Jacobi, and attempting an application of elementary geometry
to the elliptic transcendents, I make one of these theorems of
Poncelet my first objective point; but I propose to reach it, not
by the projective method of Poncelet himself, but by the less
elegant but more generally familiar processes of analytical
geometry. For this purpose I require a short series of intro¬
ductory propositions, as follows:
Pkoblem.—When two sides of a triangle inscribed in a circle
are represented by a single quadratic equation, to derive thence
the equation for the third side.
The general equation of a pair of lines intersecting at the
origin is
Ax^ + 2H xy + By'^ — 0;
and to transfer the intersection to any point whose coordinates
are c, s, we must write
A{x — Gy-+ 2H {x — c){y — s)+ B' {y — sfi = 0;
which becomes, on expansion,
Ax^ + 2Hxy + By^ — 2 (Ac + Hs) x — 2 {Bs + He) y q
{Ac' + 2Hcs + Bs') = 0;
This equation will represent two sides of a triangle inscribed
in the circle
+ y' = B\ (2
provided we take for R' the value c' + si
The loci of equations (1) and (2) have, two coincident inter¬
sections at the point c, s; our problem is to write the equation
of the line joining the two remaining intersections.
It is a familiar 'principle that, if P = 0 and ^ = 0 are the
equations of two conics, then an equation of the form P + IcQ
= 0, where k is an arbitrary constant, represents a conic passing
through the four points in which the first two conics meet; and
50
Colorado College Studies.
conversely that by properly choosing the value of k, any conic
through these four points may be thus represented. Any of
the three conics may be a pair of lines. In the present case, if
P = 0 and Q = 0 are our equations (1) and (2), it must be
possible to give k such a value that the equation P + kQ = 0
shall represent the pair of lines, one of which is the line whose
equation we seek, while the other is the line joining the remain¬
ing intersections of the given loci. But these two remaining
intersections are the two consecutive points on the circle in
which it is met by the two lines at c, s; accordingly the line
joining these points is simply the tangent to the circle at the
point c, s; that is, its equation is
cx -j- sg = PI
And if we represent the line whose equation we seek under
the form
Ix + my n = 0,
(where Z, m, and n, are quantities at present undetermined,) then
the form
{cx sy — P^) {Ix my + n) = 0,
or, as this becomes on expansion,
cZP 4- {Is + cm) xy + msy"^ -)- {cn — cH — Zs^) x
+ {ns — (fm — ms^) y — (cbi — ns^) — 0
is a form with which the equation
AP + 2Hxy + Bif — 2 {Ac + Hs) x — 2 (Ps + He) y
+ {Ad' + 2Hcs + Bs') + k (P + 2/^ — c' — s^) = 0
must become identical by giving a suitable value to k.
Assuming this identity we have for the determination of
four unknown quantities, viz., k, Z, m, and n, the six equations
cZ = A + k, Is + cm = 2H, ms — B + k,
cn — c'l — Zs^ = — 2Ac — 2IIs,
ns — — ms' = — 2Ps — 2iZc,
— dn — = Ac" + 2IIcs Bs" — c"k — ks".
The solution of the first four of these equations readily gives
The Elliptic Functions Defined.
51
the desired quantities; and the two remaining equations may
then be used to verify these results. We find
J -A-G — Be 2Hs — A.S -|- Bs ^Hc
V — ' n j 2 J ^2- — j 5 J
c' + s' c' + s'
. u , 2ilcs — As' — Be'
— A. — B, k =
c' +
If now the above values of I, m, and n be substituted in the
equation
Ix + mij + w = 0
and the latter cleared of fractions by multiplying through by
c' + s', we have the sought equation of the third side of the
inscribed triangle, viz.,
(2Hs + Ac—Be) X + (2jHc — J-s + Bs) y — {A-{■ B){c' + s'). (3
Peoblem.—If two chords of a given circle meet on its cir¬
cumference, and are both of them tangents to a second given
circle, to write the equation of the line which joins the extremi¬
ties of these chords.
This is the same as the foregoing problem, with the added
condition that the two lines which meet in the point c, s, are to
be tangent to a second given circle. Let the radius of this
second circle be r, and its centre situated at a distance a from
that of the former; but, for subsequent convenience, let the sign
of a be taken opposite to that of the abscissa of the centre,,
which we assume to be situated on the axis of X. Then the
equation of this second circle is
+ a' — (4
and that of the pair of tangents to it from the point c, s is
(r^—s') x'^ {asGs) xy + {r' — — 2ac — c^) y'
— 2 (as"'' -f- er') a? + 2 {a's — r's + aes) y (5
+ + rV — aV) = 0.
(I assume the latter equation as known, since it is given in the
text-books, .but I may remark that a handy method of obtaining
it is identical in principle with that employed in the former
52
Colorado College Studies.
problem. To wit, if P = 0 be the equation of the polar of c, s, in
respect to the new circle, thenP^ + A: (P + 2/^ + 2a.r + «'—'*^) = 0
must be identical with equation (1). This furnishes, as before,
six conditions to determine four unknowns, which in this case
are A, H, B and A:).
A comparison of equations (1) and (5) shows that the latter
is derived from the former by giving to A, H, B, the values
— s^, as + es, and — 2ac — P respectively. Then if
the same letters be replaced by these values in equation (3),
the result will be the equation demanded by the present prob¬
lem, viz.,
[2a {c- + s') + c (c' -f s' + a')] ic + s {c" -f s' — rf') ij
+ + 2ac + c'' -|- — 2;'") = 0.
It is desirable to notice at what point the line whose equa¬
tion has just been written, intersects the line which joins the
intersections of the two circles, i. e., the axis of JC. If for this
purpose we put ^ = 0 in the equation, and solve for x, replacing
at the same time c'^ -}- s'^ by R', we have, as the abscissa, m, of
the point in question,
R^ (a^ + 2ac + — 2r)
= + c (j;- -H «■)— <'
This expression does not contain s; hence if we regard the
two circles as fixed in position but the point c, s as moving,
(subject of course to the condition that it remain upon the cir¬
cumference of the circle x^ + y" = R^), we may discuss the
effect upon the position of the intersection m, 0, by supposing
the value of c alone in the formula to be varied. The equation
(7) is linear in c and in m, so that for any value which may be
assigned to one of these quantities a single real value would be
obtained for the other. But not all values of c are possible
consistently with the restriction of the point c, s to the circum¬
ference of a circle; c, in fact, cannot be greater than R or less
than — R. Hence the values of m which would be obtained by
assigning to c any value transcending these limits are equally
The Elliptic Functions Defined.
53
impossible, and it follows that there is a region upon the line
joining the centres which is never crossed by the line whose
equation is the above equation (6); and moreover that the
limits of this region or segment are the points which we obtain
from (7) by giving to c the value B and — B successively; viz.,
they are the points whose abscissas are
B[2r-(B + ay] _ BljB - afi-2^
m =
+ - {B — af '
These results are such as would be expected from a purely
geometrical point of fig /
view. If we construct
a diagram. Fig. 1, in
which two circles
P,PP,2L and TT'JV
are drawn in any rela¬
tive positions, and as¬
signing to a point P
several different situa¬
tions in succession
upon the circumference
of one of them, con-
stnict, for each posi¬
tion of P, the system
of chords as described
in the foregoing, it will be evident that corresponding to the
singly infinite succession of positions possible to P, there is a
singly infinite succession of positions of the line ilPY; and
accordingly it is to be expected that these successive lines
envelope some curve, which, in consequence of the general sym¬
metry of the figure, would be symmetrical to the axis P2P1.
Moreover, when the point P is made to traverse the circum¬
ference PiPJ/d/2, a fixed point Q on the latter becomes twice
and only twice the extremity of one of the chords 3IJV; that is,
once when the point J\I and again when the point N arrives at
Q. Hence it might be at least conjectured the that curve
54
Colorado College Studies.
enveloped by MN is of that class to which two. and only two
"tangents can be drawn from a given point; that is, that it is a
conic. The limiting positions found in (8) are the points Fj, V2,
on the axis of symmetry P1P2 at which tangents at right angles
to this line meet the curve. We may so far avail ourselves of
the analogy which the enveloped curve appears to bear to the
conic, as to name the point midway between Vi and V2 the
centre, and the distance of the centre from either of them the
semi-axis. Then, if we denote by g the abscissa of the centre,
taken with the contrary sign, and by p the semi-axis, without
regard to sign, (since for the present we shall be concerned only
with the absolute value,) we shall have
m' + m" , m' — m"
— Sr = ^ , and gy = ^ '
or, substituting from (8) the values of m' and m",
4aPP- , P[2F(P^ + a') ——fr)n
g = (g - rf)- (g-rff -■
We shall now prove analytically that the line il/iV does in
fact envelope a curve, viz., the circle, whose centre is at the
point — <7, 0; and whose radius is p.
Thoeem.—If a point move upon the circumference of a fixed
circle, and if two chords of this circle, which meet in this point
and hence move with it, continually touch a second fixed circle;
then the third chord which joins the extremities of the two
former, will also continually touch a fixed circle. Moreover,
the three circles have a common radical axis.
When g and p represent any two quantities whatever, a
circle with radius p and centre — g,0 has the equation
P + y- + ^gx + g' —pi" — 0;
and the condition that this circle may be touched by any right
line,
Ix + my n — 0,
is found by eliminating one of the variables, and forming the
condition that the resulting equation may have equal roots. If
The Elliptic Functions Defined.
55
y be the variable eliminated, this condition appears at first in
the form
{gm^ + = {V + m^) (pW — + n') = 0;
but is easily reduced to the simpler statement
p \/V 7n^ — gl — 71.
And if in this formula we substitute for g and p the values
given in the equations (9), and for Z, 771, and r, the coefficients of
equation (6), remembering that we find that the
formula is identically satisfied; and thus it is shown that how¬
ever the point c, s, may be situated on the circumference
-j. 2/2 — chord represented by (6) is tangent to the
circle whose position is defined by (9). The equation of this
circle, as written at the beginning of the present paragraph,
becomes, when g and p are replaced by their values,
{E" — a'Y {x' + y') + 8a7''B' x — E {E — a'fi „
+ Ar'E {B' + a') — Ar'B' = 0. ^
To prove the second part of the theorem, we have only to
bear in mind that the equation of the radical axis of two circles
is obtained by subtracting the equation of one circle from that
of the other, having first multiplied either by such a factor as
may be necessary to render the coefficients of x^ and alike in
both. Combining in this way the equation x' y'' — B^ = 0
with the two equations (4) and (10) successively, we obtain in
each case as the equation of the radical axis,
2ax + B' + a' — 7-' = 0. (11
Jacobi cites the foregoing theorem as due to J.-V. Pon-
celet, and occurring on page 326 of his celebrated work, " TmitS
des P7~opriStSs Projectives des Figim^es." In the edition of
1865 I find the theorem on page 315, in a form which may be
translated as follows:—
" If an angle, being at the same time inscribed in one circle
and circumscribed about another, be made to move while sub¬
ject continually to these same conditions, then the chord which
56 Colorado College Studies.
it subtends in the first of these circles will envelope a third
circle which will pass through the points of intersection of the
two former, or have in common with them the same secants,
whether real or ideal."
By an "ideal secant" Poncelet means a real line, whose
points of intersection with the curve are imaginary. The
description " a common real or ideal secant" applies therefore
to the radical axis of two circles, which in all cases fulfils the
analytical condition for passing through the common finite
points of the two curves; but, in the case of circles which do
not meet in real points, can be called their common secant only
in an "ideal" sense. Jacobi appears to prefer the designation
for this line which was introduced by Steiner, viz., " the locus
of equal tangents,"—a name given in reference to the well
known fact that whether two circles meet in real points or not,
the tangents drawn to both from any point of the radical axis
which is exterior to them, are equal in length.
The proof given by Poncelet for the theorem depends
upon the properties of conics having double contact with one
another.
The property of the radical axis, to which reference has just
been made, furnishes an easy geometrical solution of the follow¬
ing problem:
Having given a circle, a chord of the same, and a line as
radical axis, to determine the circle which has, in common with
the given circle, the given line as a radical axis, and which
touches the given chord. (See Fig. 2).
From C the center of the given circle, draw a line CD per¬
pendicular to the given radical axis. On this line, extended
indefinitely, lie the centers of the whole system—or "pencil,''—
of circles which have with the given circle the given radical axis.
Produce, if necessary, the given chord PM to meet the radical
axis in Q. Determine in the usual manner, a point B on the
given circle so that QR would be a tangent. With Q as center
and QB as radius strike an arc BTG meeting the given chord
I
The Elliptic Functions Defined. 57
PM in T. This is the point of
contact. From T draw Tc per¬
pendicular to PM, and meeting
CD in c. The circle with center d
c and radius cT is the circle re¬
quired. For it touches PM,
while the tangents QR and QT
are equal, so that QD is, as re-
quired, the locus of equal tan¬
gents of the two circles.
There are two solutions. For
the arc RTG, extended, will meet
PQ produced, if the produced
part be made equal to TQ. We may state this as follows:
Of all the circles having a given radical axis in common, two
and only two are tangent to any given line, and their points of
contact lie on opposite sides of the radical axis.
In all of the foregoing the relative positions of the circles
considered, or, in the analytical part, the relative values of R,.
r and o, have been subject to no limitation. We have now,
however, to impose a restriction in this respect.
Theorem.—-When two chords of a circle, which meet on its
circumference, are tangent to a second circle which lies wholly
within the former, the third circle, which is touched by the line
joining the extremities of these chords, from whatsoever point
of the circumference they are drawn, lies also wholly within the
first circle.
If this joining line be MN of Fig. 1, (supposed indefinitely
produced) it is, in any given position, as we have just seen,
tangent to two of the circles which have a common radical axis
with the two given circles. If the point P be moved, and the
line MN move irf consequence, it cannot of course remain
tangent to both; and the one to which it does remain tangent
has been already found; being uniquely determined, from among
all the circles having the before-mentioned radical axis, by either
5
58
Colorado College Studies.
one of the two elements given in equation (9). Now if the
second given circle lie wholly within the first its radius r is less
than R — a, that is,
< (i? —
But the distance g between the centres of the first and third
circles,^as given in (9) may be factored as follows:
_ p
^ ~ {R — af ' {R + af '
Of thAe factors, the first has just been shown to be less than
unity; and the second is so likewise, since
(jB — ciY — R^ — 2aR -j- > 0.
Add 4ajB = 4ajB
{R + o,y = + 2aR + a' > 4:aR.
We may here assume a and R are taken in their positive
values; hence, on the same supposition with regard to g, (which
must be positive if a and R are so),
g < R.
Hence the centre of the third circle is within the first; there¬
fore the third circle either lies wholly within the first or inter¬
sects it; but the latter alternative is not admissable, since, the
three circles having a common radical axis, if two intersect, the
other must pass through the points of intersection, which would
be contrary to the hypothesis; hence the tbird circle lies wholly
within the first.
It will accordingly be assumed in future that the circle whose
radius is R is exterior to all other circles of the diagram which
have a common radical axis with it: each of the latter forming a
member of an infinite series of circles, the maximum of which
coincides with the circle — R^, and each succeeding circle
lies wholly within the preceding one, until the lower limit is
reached in the point, or circle of zero radius. This point,
marked G in Fig. 2, is there determined as the intersection of
the arc RTQ with the axis CD-, and, by the application of the
The Elliptic Functions Defined.
59
same principle then employed, would be similarly found on a
circle described from any other point of DQ as a centre, with
radius equal to the tangent to the outer circle from that point.
It is in fact a point common to all the circles that cut orthogon¬
ally the system whose radical axis is DQ, and is fixed in posi¬
tion as soon as the circle PRM and the line DQ are given; or
conversely, this circle and the point G will determine the line
DQ. This circle, line, and point will be assumed as given in
position in subsequent constructions, and are to be regarded as
remaining unchanged in passing from one construction to
another.
When in addition we have given a chord, as PM in Fig. 1, in
one of its positions, we are already able to construct the remain¬
der of the triangle PMN, and the circle which, in the successive
positions of the triangle, is enveloped by 3IN. For we may first
construct the circle TT'W as directed in the construction
attached to Fig. 2; we may then locate Ton its circumference
by making PT — PT'; the line PT produced determines Nand
accordingly MN\ and finally a second application of the con¬
struction of Fig. 2 gives the circle to which 3IN must remain
tangent. As we have to attend only to circles interior to the
given circle, no ambiguity is encountered at any stage of the
process.
If on the other hand the chord MN is given, and it is
required to complete the triangle by drawing P3I and PN, we
may first construct, as above, the circle tangent to 3IN, — in the
figure, V1SV2 — and then draw a tangent to this circle at
either of the points F, or where it meets the axis. If ilfiWi
is such a tangent, and Piilfi a line joining one of its extremities
to an extremity of the diameter P1P2, we can construct that circle
of the system which is tangent to Pjilfi; and the symmetry of the
figure shows that the same circle will be tangent to PiiVj as well.
Accordingly, if tangent lines are drawn to the circle from M and
N, they must meet on the circumference of the given circle at a
point P, and the triangle will have been constructed as required.
/
60
Colorado College Studies.
In this construction there is evidently an ambiguity. We
may draw the tangent to the circle V-^SVi at either point Fj or
Fa, and join its terminal points upon the given circle with either
Pi or Pa. It is evident, however, that we do not thus obtain four
results, but only two; since the two sides of the triangle PiM^N^
will, on the movement of P, envelope the same circle as those
of PaiipWa, and those of PiJ/aWa tbe same as PaJ/jiVi.
The analytical parallel to the geometrical construction just
given consists in determining a and r, the elements of the circle
TT'W, in terms of those of V1SV2, that is, in terms of g andjp.
And the double solution of the geometrical problem answers to
the ambiguity in the sign of p, of which, in equation (9), we
fixed only the absolute value. We now notice that 771' is the
abscissa of the point of contact of the base of that triangle
whose vertex is at P,, where c = P; and m" corresponds in the
same way to the vertex at P2, where c = — P. Hence if the
base of the triangle is on the same side of the circle FjSFj as
its vertex is,—as in the figure,—we obtain the radius of the
circle with its positive sign by the formula p = ^ (m' — m"),
but if the triangle were the radius would be of oppo¬
site sense and denoted by the formula p = ^ (m" — 771'). As¬
suming that the former is the case, we have
p + g — — m" and p — g = m'
whence, by equation (8),
P + 9= ^E-ay
and
If we take from one of these the value of P and substitute it
in the other we obtain for the unknown quantity a a quadratic
equation, whose roots are
a — ~[^R + p ± V(P+ pY — . (12
The Elliptic Functions Defined.
61
Here there appears to be a new ambiguity. Both of these
roots are real, but one of them, as is obvious on inspection is
greater than Rj that is, the circle to which it belongs has its
centre outside the circle ifi = R^-, hence it is not a member
of the series of circles to which our attention is at present
restricted. But the other root, while of the same sign as g is
less than gj whence the circle corresponding to it lies betweeen
the circles whose radii are R and p, and so exterior to the latter.
We learn accordingly, that starting from a given base UN we
can always determine in one and only one way a triangle PMN
whose vertex shall lie on the opposite side of MN from the
circle to which the latter is tangent, and whose sides, meeting in
P, shall touch a circle exterior to that touched by MN.
We can now solve, both analytically and geometrically, the
following problem:
Within a given circle to determine the position of a second
circle, having in common with the first a given line as radical
axis, and such that a polygon of 2" sides may be at once
inscribed in the first circle and circumscribed about the second.
The process and the result
are entirely independent of the
position of the first vertex P of
the polygon, which may be as¬
sumed arbitrarily upon the cir¬
cumference of the given circle.
The first polygon to be con¬
structed is that of two sides,
which consists of a chord ex¬
tending from P to some other
point of the circumference and
thence back to P. As the two
sides coincide, the inscribed circle is of zero radius, hence con¬
sists of the point G, geometrically determined as in Fig. 2. The
second vertex of the polygon is therefore fixed at the point P'^
where PG meets the circumference.
fig. 3.
Colorado College Studies.
The analytical determination of the point G presents no
difficulty. If the length of CD be denoted by d, that of a tan¬
gent from D to the given circle will be V d' — since such a
tangent forms a right triangle with CD and the radius to the
point of contact. Therefore the distance DG is Vd' — R', or
CG is (Z — V d*' — R\ '
We now proceed to the construction of the quadrilateral, and
its inscribed circle.
The. construction has already been in substance given. A
chord at right angles to AD is drawn through G, and through
H, its extremity, a line AH is drawn, and extended to meet the
radical axis at Q. The distance QG, laid off on this line from
the point Q, fixes t, the point of contact, whence both the centre
c and radius ct of the circle become known. Tangents to this
circle are drawn from P and from P', and these tangents, meet¬
ing at Pi and P/, compose the quadrilateral.
Analytically, we apply equation (12) to determine a, which is
cC of the figure, having for g the known distance GC, and for_p
the radius of the circle at G, which is zero. Having determined
a, we find r from equation (11) in which we replace x by its
known value, — d. The formula then is
H a' — 2acZ.
Each process,—the geometrical and the analytical,—may
now be applied anew in the case of the octagon. A tangent at
right angles to AD is drawn to the circle whose centre is c, and
the chord AH' is drawn to the point where this tangent meets
the outer circle, etc. For the analytical computation the equa¬
tions (12) and (11) are again employed, but now g and p have the
values which were previously denoted by a and r, while a and r
denote the elements of the new circle inscribed in the octagon.
And thus the process may be carried on as many times as
desired.
A practical difficulty occurs in the geometrical construction,
on account of the use made of the point in which AH' meets
The Elliptic Functions Defined.
63
the radical axis, for as the number of sides of the polygon
increases these lines approach parallelism. It is to be noted,
however, that this part of the construction is merely the appli¬
cation of the method given for finding on a given line the point
of-contact of a tangent circle which has in common with a given
circle a given radical axis. A second method for solving this
subsidiary problem will be given later, and thus the above-noted
mechanical difficulty will be obviated.
It seems well to notice here,—although it is aside from the
immediate purpose,—that the equations thus far obtained serve
also for the case of a triemgle inscribed in one circle and cir¬
cumscribed about another; and hence for the determination by
the above process of the elements of the inscribed circle for a
polygon of 3 X 2" sides. In Fig. 1, PMN will be such a
triangle as just described, provided the circle touched by the
side MN is identical with that touched by PM and PN, that is,
if g and p are equal to a and r respectively. Applying this con¬
dition in the value of g given in equation (9) we have.
4:aPR'
{P' — a'Y '
Dividing through by a and extracting the square root we
obtain
B' — cd = 2rB, (13
as the relation which must subsist between the radii of an ex¬
terior and an interior circle, and the distance between their cen¬
tres, in order that a triangle inscribed in one may be circum¬
scribed in the other. If B and a be regarded as known, r may
be found geometrically by constructing the proposition
2B : B + a = B —a : r.
When the circles have been determined, the radical axis may
be found either geometrically, by well-known constructions, or
analytically by equation (11); and thenceforward the work pro¬
ceeds as in the foregoing paragraph.
The form of the above equation (13), (which is ascribed to
64
Colorado College Studies.
Euler), is noteworthy as containing only the symbols R, r
and a with no auxiliary quantities. The data of this and the
preceding paragraph afford, of course, the material for writing
similar equations for polygons of 2" or 3x2" sides, if, instead of
introducing as known quantities in the equations the elements
of previously solved problems, we should eliminate all such
quantities. For polygons not belonging to these groups an in¬
dependent investigation would be necessary for every polygon
in number than eight, and the general method indicated by
Jacobi has since been applied to polygons of still higher num¬
bers of sides by F. J. Eichelot and others; but, so far as I know,
without appending methods of geometrical construction. *
It is especially to be noticed, in the problems of the two pro¬
ceeding paragraphs, that when an initial vertex has been
chosen, the remaining vertices are thereby fixed, not only for
that polygon, but for all that arq successively derived from it by
doubling the number of sides; and so that if, in passing in a
determinate direction around the polygon, the number of sides
between the two vertices is to the whole number as m to n, this
holds true for the same two points in all the polygons subse¬
quently derived. These two points, then, always have between
• The memoirs of Klchelot are to be found in Crelle's Journal vols. 5 and 38; there
is also an article in vol. 81 of the same Journal (1875), by Max Simon; the latter
paper succeeding a Latin dissertation by the same author which appeared in 1867.
These writers have made extensions of the problem in several directions.
of k sides (where k is an odd num¬
ber) in order to apply the preced¬
ing method to extend the result to
k X 2" sides. Equations between
R, r and a had been obtained before
the date of Jacobi's memoir, cited
at the beginning of the present
paper, by Nicolaus Fuss and by J.
Steiner, the former of whom ob¬
tained formulae applicable to each
of the polygons of sides not greater
The Elliptic Functions Defined.
65
them of the whole perimeter of the polygon (when this is
estimated by the number, not the length of the intervening
sides,) however great the number of sides may be made.
Let us now return to the consideration of the former of these
last two problems—viz., that relating to the polygons of 2" sides,
—and let us suppose that there is given, as in that and previous
problems, the circle of radius R, also the right line which has
heen previously used as a radical axis; and we will define the
position of the latter a little more strictly than heretofore by
requiring that the diameter to which it is perpendicular, which
may be called the initial diameter, shall be placed horizontally,
while the radical axis itself stands on the left side of the circle.
This circle we will name the circle of the amp)litude. To avoid
unnecessary repetitions of a statement already familiar, let it be
understood in future that whenever a polygon is mentioned as
inscribed in the circle of the amplitude, it is meant that the same
polygon is also circumscribed about one of the circles which
constitute what we shall henceforward call the interior system*
i. e., those which are within the circle of the amplitude, and
have with it the given line as radical axis—the particular circle
touched by any polygon of 2" sides being always uniquely de¬
termined to each value of w, by the method already explained.
Let us now suppose another circle to be drawn, exterior to the
circle of the amplitude, and hence, of course, to the whole in¬
terior system, and not having with them the radical axis which
they have in common, but being instead, concentric with the
circle of the amplitude. We will call this new cii:(3le the circle
of the argument. Its radius might, for our present purpose, be
of any convenient length. If, after defining the elliptic func¬
tions, we pursue the consideration of them sufficiently far, we
may discover a reason for choosing a particular length for this
radius, but we will at present be content to regard it as arbitrar¬
ily taken of a length whose ratio to that of R we will denote by
"^K ; TT. The right hand extremity of the initial diameter, in
66
Colorado Gollefje Studies.
either of these circles, we will call the origin of arcs, for that
circle.
Suppose now, that a polygon of 2" sides, say a quadrilateral,
is inscribed in the circle of the amplitude, having one vertex at
the origin; and at the same time a regular polygon of the same
number of sides—a square—is inscribed in the circle of the
argument, this also havihg a vertex at the origin. All polygons
inscribed in this circle are to be regular. In order to avoid con¬
fusing the diagram, the vertices only of either set of polygons
tices are 6/, hf bf hf, and the corresponding new vertices in
the other circle are Bf Bf B^, Bf Next, the polygon of
sixteen sides may be constructed, adding the new vertices
l>i", bf,... bf in one circle and Bf, Bf,... B^' in the other.
And so the process may be continued as far as desired, with,
the result of fixing—in a perfectly definite way in each case—
as many points as we please on one circle, and the correspond¬
ing points on the other.
We are now able to define, for any point on one circle, its-
corresponding point on the other. Let a point be given at
pleasure on the circle of the argument, and also let an arc of
the circle of the amplitude be stated in magnitude but not in
Ag- i
B, •
are noted in the figure.
(Fig. 4.) The trapezium
inscribed in the circle of
the amplitude is Ab, Fb,,
and the square in the
circle of the argument is
XB1EB2. Next let an
octagon be inscribed in
each circle. A new ver¬
tex is now inserted be¬
tween each of the former
vertices and the succeed¬
ing. In the circle of the
amplitude these new ver-
The Elliptic Functions Defined.
67
position;—merely a definite fraction of the circumference. We
may then continue bisecting the arcs of the fcircle of the argu¬
ment, at the same time fixing on the other circle the points which
correspond to these points of bisection, until one of two things
must take place. Either one of the points of bisection falls on
the given point, in which case its corresponding point is un¬
equivocally determined, or else two points of bisection will be
found, containing the given point between them, and such that
the arc of the circle of the amplitude, contained between their
corresponding points, is less than the assigned arc. But this
will be true, how small soever the assigned arc may have been.
There is then a limiting position on the circle of the amplitude,
corresponding to the given point on the circle of the argument.
It may be remarked that to fix approximately the point cor¬
responding to a given point, with sufficient accuracy for a
geometrical illustration, will not in general require many bisec¬
tions, for the circles within the circle of the amplitude, inscribed
in the successive polygons, rapidly approach coincidence with
the latter circle,—as a result of which fact, a point within an arc
of this circle soon comes to divide the arc in sensibly the same
ratio in which the corresponding arc of the circle of the argu¬
ment is divided by the corresponding point.
Now let a point move on the circle of the argument with a
uniform velocity, and in a positive direction of rotation, starting
from the origin of arcs; and let a second point move on the
circle of the amplitude, starting from its origin, and moving so
that it always occupies the point corresponding to that occupied
at the same instant by the former moving point; whence it is
evident that its motion cannot be uniform, but will be more
rapid in the first part of the semi-circumference than in the
latter part. Then to any arc of the circle of the argument, be¬
ginning at the origin, corresponds an arc of the circle of the
amplitude, beginning at its origin; viz.: they are the arcs
traversed by the two points in the same interval of time. These
arcs are denoted by 2m and 2x respectively, and the halves of
•68
Colorado College Studies.
these arcs, viz., u and x, are named respectively the argument
and the amplitude. So that to find the amplitude correspond¬
ing to any given argument, we have first to double the latter,
then to find the point on the circle of the amplitude correspond¬
ing to the termination of the donbled arc, and finally to bisect
the arc included between the point so found and the origin.
It is to be remarked that the argument, for which the cor¬
responding amplitude is thus found, is given as an arc of a circle
2K.
whose radius (if we make R unity) has been taken to be —
hence its circumference is 4K. In other words, the argument
is supposed to be given, not in absolute value, but by its ratio
to a constant, isT; just as an arc of the circle of unit-radius is
often most conveniently given by its ratio to -. When the point
moving on the circle of the argument has described the whole
circumference 4K, so that u = 2K, the point on the circle of
amplitude has also completed its circuit, and the relations of
position between these points for all greater arcs are the same
as for the arcs by which these exceed this respective circumfer¬
ences, hence the amplitude of 2nK + u exceeds by m: the am¬
plitude of u. But as on the one hand it is totally unnecessary
to the foregoing construction to know the value of .K'^so con-
Fig. s
versely, the construction
affords no means of det er-
mining K. The considera¬
tions by which a definite
value is assigned, though
external to the main purpose
of the present paper, will
be indicated in a concluding
paragraph.
The fixed parts of the fig¬
ure, whose relation of mag¬
nitude is material to the
construction, are only the circle of the amplitude and the radi-
The Elliptic Functions Defined.
69-
cal axis of tlie system; and accordingly, when the scale of the
diagram has been fixed by choosing a value of R, there is but
one independent constant which is required to determine its
proportions that, namely, which fixes the position of the radi¬
cal axis. It has been found most convenient to define this posi¬
tion by means of the ratio of the diameter of the circle of the
amplitude to the distance of its origin from the radical axis.
AF
This ratio, which is —^ in the figure, is denoted by and the
quantity k is called the modulus.
To turn from the fixed to the variable elements of the figure
it is manifest that whatever is dependent on the magnitude
of (f may also be regarded as depending on that of u. Thus the
trigonometric functions of <p are functions of u as well. In par¬
ticular, the sine and cosine of y, regarded as functions of the-
argument, u, are denominated respectively sn u and cn u, (read
"sine-amplitude M" and "cosine-amplitude m"). If P be the
termination of the arc 2y, (Fig. 5) these two functions are evi¬
dently geometrically represented,—at least so far as regards
their absolute value,—by the ratios which the distances of P
from the two extremities of the horizontal diameter FA bear to
the length of this diameter. If now we also draw that circle
of the interior system which is tangent to the chord AP, the
right triangles FPA and cTA are similar; and if r and a, as
before, denote cT and cC, we easily find, to determine the length
of AT, (which we will call t,) the equation
f={R + ay—r\ (14
Whence
AP AT
sn u =
and
FP * cT
cn u =
• (16-
FA cA R + a ^
To these two functions*is added a third, called the delta of
y or the delta-amplitude of u,—written dn u,—and defined as.
70 Colorado College Studies.
the ratio in which the chord of 2^' is divided at the point of con¬
tact of its tangent circle of the interior system; or as the ratio
in which the diameter of the circle of the amplitude is divided
at the center of the same interior circle. That is,
TP cF _ E — a
a" u - ^ - B + a' ^
"We may also express k' in terms of the same letters,—not
forgetting, however, that Ic^ is constant, while a and r vary with
The length of CD as found from equation (11), is
R' + (d — P
CD =
2a
For AD, we must add R, and then divide 2R by the result to
obtain D, whence
P = (18
(E + a.)- — r-
But from the above value of dn u, it appears that
7 . 7 X _ 2a _ AaE
(1 + (In v) (1 (In ") - + o ■ i2 + a ~ +
whence
1 — (hdn _ 4r(J?
snhi (EaY—"
Comparing this with the foregoing value of Id we obtain the
equation
1 — (In'u
- lY
SU'U
or
(hdu = 1 — Psidu. (19
The definitions of the three "elliptic fiincfions," as stated in the
analytic form, are accordingly as follows:
sn u = sin f; cn u = cos <p; dnu — \dl — JY sin^ <p . (20
The first and second of these definitions determine the sisn as
well as the magnitude of sn u and'mi u: the sign of dn u is
taken always positive.
The Elliptic Functions Defined.
71
Another geometrical definition of dn u may be obtained as
follows. Let 31 be any point on the circle of the amplitude, the
termination of an arc ^<p', and let its coordinates be xJ and y'.
The diameter FA is divided at L, the foot of the ordinate, into
the segments + a;' and R — x', which are proportional to the
squares of the chords F3I and A3I, and hence to the squares of
cos <p and sin respectively; hence (if the arc 2u' correspond to
2?') we have
a , R-\-x' , ,, , R — x'
cn u — —— and sw u = —— (21
and from the latter equation •
x' = R {1 — 2sifu').
Now the square of the distance of any point x', y' from the
point c is
y''^ + x''^ + 2ax' + ci'
whence, if t' denote the length of the tangent to the circle whose
centre is c,
_ yli _j_ _j_ ,.2.
But the point being 31, on the circle of the amplitude, we may
put for y'^ + a:" the equivalent and for x' in the succeeding
term the value just obtained, and find
+ 2aR (1 — 2sn- u') + — 7*
+ 2«i? + — 4o-Rs?t^ u'
or finally
f = [ (ii + a)' -(l - sn'.
The former factor is the square of the tangent AT, as given in
a former equation, (14), and the latter is,—see equations (18)
and (19),— ^
l—-ldsn^u' or dn^u.
Hence the value of t' is briefly expressed
t' — t dn u'.
(22
72
Colorado College Studies.
Now as 31 was taken at pleasure on the circumference, it
stands in no special relation to the particular circle whose
centre is c, hence we may define the delta of an arc <p to be the
ratio which the tangent drawn from the extremity of 2^? to any
circle of the interior system bears to the tangent to the same
circle drawn from the origin of amplitude.
If P and 31 be any two points of the circumference, as in
Fig. 2,—the arcs AP and A3I being respectively designated as
2y' and 2<p", and the corresponding arcs of the circle of the argu¬
ment as 2m' and 2m",— then the tangents from these points to
any circle whatever of the interior system are in constant ratio,
to wit, dn u': dn u". Two limiting cases are to be noted. First,
the tangents in the case of one of the circles will form one right
line, the chord P3I, which is then divided, in the ratio just
named, by the point of contact of the interior circle. Second,
the circle to which the two tangents are drawn may vanish in
the point G; it then appears that the two distances PG and
3IG are to each other in the same before-mentioned ratio.
Combining these two statements, the triangle PG3I has its base
P3I divided at the point T in the ratio of the sides PG: 3IG',
hence it follows that a line joining G io T would bisect tbe
angle PG3I.
Two consequences follow immediately. The first is the
promised second solution of the problem: On a given line to
find, by a geometrical construction, the point at which it is tan¬
gent to one of a given system of non-intersecting circles which
have a common radical axis. The solution is: Find, as in the
previous construction, a point G, which represents a vanishing
circle of the system; connect this with the two points P and M
in which the given line meets any other circle of the system,
(for in the general statement of the problem, just given, the
circle of the amplitude has nothing to distinguish it from the
others;) the point in which the given line is met by the bisector
of the angle PG3I is the required point of contact.
The second consequence is still another geometrical defin-
The Elliptic Functions Defined.
73
ition of the function dn u, which may now be defined to be the
ratio which the distance of the termination of the arc 2^^ from
the fixed point O bears to the fixed distance GA.
We have hitherto regarded the polygons which have been
inscribed in the circles of the argument and amplitude, as figures
of the same character as the polygons of Euclid's Elements;—
such, that is, that in passing along the sides from one vertex to
the same vertex again, only one circuit is made about the center
of the circumscribed circle. But this restriction is entirely
unnecessary, and the geometrical constructions as well as the
analysis can easily be applied to the case of polygons whose
sides make any desired number of circuits. Suppose, e. g.,
that in the construction of Fig. 3., we had chosen to regard the
arc extending from P to P again as consisting of 6:r instead of
2-. The polygon of two sides, PP', would have'been constructed
as before, but the distance on the* circumference from P to P'
requires a whole revolution and a half. So I[also the quadri¬
lateral presents the same appearance as before,ibut the order of
the vertices is PP/ P' Pj. But coming'^tojthe octagon, we use
the chord FH' instead of AH' as determining the tangent circle,
and place the second vertex of one fignre](the^first being at P),
on the arc Pp'. Thence forward we proceed as before. In a
similar manner we may form polygons which make|[five circuits,
or any other number. In fact, if P beja'point on the circle of
the amplitude, the extremity of the mth side (counting from A)
of a polygon of 2" sides, then AP will be the side of a polygon
of 2" sides, all of which touch one circle of the interior system,
and the last of which at the close of m circuits of the circumfer¬
ence, returns to A. And on the same principle by which we
defined to every point on the circle of the argument its corres¬
ponding point on the circle of the amplitude, we may regard the
chords of any two corresponding arcs, 2w and 2f, measured from
the origins of the two circles, as the initial sides of inscribed
polygons.
6
74
Colorado College Studies.
But instead of beginning at the origins, we may start from
any two corresponding points; the interior tangent circles will
be the same. Whence it appears that if « and a' be any two
equal arcs of the circle of the argument, and yJ and y the cor¬
responding arcs of the circle of the amplitude,—i. e., having
both extremities of each at points corresponding to the extrem¬
ities of a. and a',—the chords of yJ and yS' will be tangent to one
and the same interior circle.
From this follows immediately,— at least for the case of
the interior system of circles, and it is not difficult to see how
this proof might be generalized,—the truth of another theorem
of Poncelet, which, in the treatment of that author, precedes
the one already quoted;—from which, indeed, he derives that
one as a special case. It is as follows: (op. cit., p. 312.) "If
three circles, situated in the same plane, have a common secant,
real or ideal, and if there be inscribed in one of them a series
of triangles ABC whose sides AB, AC touch respectively the
two other circles, the third side BC of the triangle will contin¬
ually remain tangent to a fourth circle, having the same secant
with the foregoing three."
In the preceding paragraphs, the names belonging to the
elliptic functions, which are usually defined by the aid of the
calculus, have been applied to ratios presenting themselves in a
geometrical figufe. In order to show that these ratios really
sustain such relations to one another as are known to characterize
those functions, and hence are entitled to the names, two courses
might be pursued. Either differential expressions might be
deduced which should lead to the ordinary definitions, or some
special property, which, when taken in connection with the rela¬
tions already given, will distinctively characterize the functions,
might be shown to hold true of the ratios in question. I prefer
the latter course, and find the property suitable for the purpose
in the "addition formula." This is a formula expressing the
functions of the sum of two arguments in terms of the functions
of the arguments themselves taken separately.
The Elliptic Functions Defined.
75
Let U and T', (Fig. 6) be the terminations of two arcs of
the circle of the argument, of lengths respectively denoted by 2u
and 2v, and let P and J be the corresponding points of the
circle of the amplitude. A circle of the interior system is
drawn, tangent to the chord AJ. Then if W and Z are the
terminations of arcs 2« + 2v, and 2u — 2r, they correspond
respectively to ilJ and N, the extremities of chords drawn from
P, tangent to the same interior circle. I use, as before, r to
denote the radius of this circle, and — a for the abscissa of its
center, and designate the co-ordinates of P by c and s. The
line MN is then the same as that the equation of which was
written, in equation 6. We have seen that we can express the
functions sn (n + r) and cn (u + v) in terms of the abscissa
of the point 31. In obtaining the abscissa from the equation,
we shall necessarily find at
the same time that of the
point N, and thus derive
simultaneously the formulae
for addition and subtraction
of two arguments.
To eliminate y between
the equation of 3IN and ^
that of the circle of the am¬
plitude we have to replace
that number by ;
and if at the same time we
a
put V for s we have:
Fig. 6
(a'c + 2aP' -f cR') cc + (R' — dd) s/{R' — d) (R' — P)
P- {d + 2ac + — 2r^) = 0.
On clearing of radicals, collecting terms, and dividing by P',
this equation is readily reduced to the form,
d -f 2ac -f P-)' a;^ + 2x (dc + 2aW + cP')(-f- 2ac -J- P' —
+ {dc + 2aR' +cR'y — ir'R' (a'' + 2ac + R')
+ 4r*P' = 0.
76 Colorado College Studies.
In solving this, it is convenient to denote the quantities
a' + 2ac + i?' and arc + 2ai2' + cR^ by A and B respectively.
The equation is then written
AV + 2Ba; (A — 2r^) + — 4A.rR' + = 0;
and is solved without difficulty, yielding
B(A — 2r^) ± 2r a/ {A — r") {A-R- — £") .
— X-
whence we have, for the values of sn^ (it + v) and crd (it + t')
respectively.
R — X A'R + AB— 2Br' ± 2r\/{A — r") {A'R' — B')
2R ~ 2A'R
and
R + X A'R —AB + 2Br' T 2r V(A —r") (A'B — B')
2R ~ 2A-i2
As these are to be perfect squares, it is natural to inquire
whether the common radical term may not be, in each numer¬
ator, the double product of two factors whose squares make up
the remaining terms. To test this in the case of the first frac¬
tion, we may put
m-— A^R ^ AB — 2Br^, and mn = rA/{A — r-){A^R^ — B^),
and then forming (m^ -|- — 4:mV, we obtain a perfect
square, from which we have
m^ — rd = A'R + AB — 2ArR.
Hence we have at once the separate values of and n^, and
may rewrite the value of srd (u + u) as follows:
R-x _rXAJ?-B)±2iV(A-r=)(A^B^-#)+(A-r^)(AB+B)
2R 2A-R '
and proceeding in a similar manner with the other fraction, we
shall obtain
R+x _ r^{AR+B) T2r\/{A—r-){A'R'—B'}+{A-'d'){AR-B).
2R ~ 2A'B
We have now to express these fractions in terms of the func-
The Elliptic Functions Defined.
77
tions of u and v, for which the following values are furnished
by the preceding equations, (15) to (18), and (21),
„ R — c , + c
- 2R cnu- 2^
, (i2 + a)^ — r , R
^ dnv =
also H =
(25
(-R + a)' R + a R + a
4aJ2
{R+af — r''
No value has hitherto been found for dn u, in our present nota¬
tion,—i. e., where 2m corresponds to an arc of amplitude termi¬
nating at c, s;—hence we must compute one from the formula
d-ii'u = 1 — k^snhi. "VVe have
AaR R — c
dnu
{R + aY — r'' 2R
^ 2a {R — c) _ + 2ac -|- R^
(26
(jR + ®)" — (-R + «)^ —
The substitution of these values in the foregoing fractions
presents little difficulty. Beginning, in the first fraction, with
the term r^{AR — B), we have to evaluate in the first place the
factor AR — B, by substituting for A and B the polynomials
which they replace. We thus find this factor equal to {R — c)
{R — ay. We recognize in this the product of the numerators
of the above values of sn^u and dn^v, and in the other factor, r^,
that of cn^v. The denominators, all multiplied together, amount
to 2R{R -|- afi, and by this quantity, therefore, we will divide
both the numerator and denominator of the value of —— In
(I'Ai? + 5)
the last term of the numerator we now have 2i? {R + a)*
But AJ? + B directly reduces, (as above, but with change of
sign) to {R + c)(i2 + afi. Hence 2E{R + aY
i.1 e ^ -A — a^ + 2ac-t-i2^ — r®. , ,, . .
remains the factor , „ .—^, or , —^ j and this is
(R + afi (R + ay
evidently sn^v dn^u.
78 Colorado College Studies.
In the numerator of the second fraction the same factors
occur, the arrangement alone being different. It only remains,
therefore, to evaluate the denominator which is common to
both, and which, when divided by the same quantity as the
U . 11 £ + 2ac +
numerator, becomes Tv;—; rC' or the square of ——•
(J2 + a)* ^ (iJ + a)''
But we have just found that
=sn-vdn-„, and =
hence the denominator must be the square of srrv dn-u + cn\
and when we put for dnru and cri'v their values 1 — Ji^sri'u and
1 — snrv, this becomes
(1 — sn-u sn-vy.
When, now, all the factors of our two formulae (23) and (24)
are replaced by the equivalent expressions in terms of the func¬
tions of u and v, the two members of each are perfect squares,
and by extraction of the square root we obtain
, snucnvdnv ± snv cnu dnu
sn [u ± V) = = pi—5 ^ > (27
1 — k' sn-u sn-v
, . cnu C71V snu snv dnu dnv
en (u±v)= q p;—5 ^ . (28
i — k' sn'u sn'v
The extraction of the square root, both here and in the
previous solution of a quadratic equation in x, yields a double-
valued result. But we may remove all ambiguity by considering,
in the first place, that these formulas cannot be affected in sign
by a change in the value of kf, as by making it approach zero;
while secondly, for k = 0, the foregoing equations reduce to the
trigonometric formulas for sin (m + i") and cos (n + v). The
radical axis is in that case at an infinite distance, and all the
circles are concentric. But the above arrangement of signs is
that which occurs in the special case of the trigonometric for¬
mulas, and is therefore the right one in general. The same con¬
clusion might of course be reached by an examination of the
figures, in detail.
The Elliptic Functions Defined.
79
In order to deduce the formula for dn {u + v), let us con¬
sider another diagram, (Fig. 7), in which, in so far as the same
letters are used as in the
preceding, they stand for ^
the same things; viz., the
double arguments and
2v terminate at U and V
respectively, and these
points correspond to P and
to J. Let us name the
arcs AP and AJ, 2<p and
2^'' respectively, and let an
arc AJ', of a length 2v'', be
measured from A in the
negative direction. Join
PJ', and draw the circle of the interior system tangent to this
chord. As this circle is not the same as was drawn in Fig. 6,
its centre is marked c' instead of c. We also denote the abscissa
of c' by — a', and the radius of the new cirle by r'. In the
former figure a chord tangent to the interior circle would always
terminate in points such that their corresponding points on the
circle of the argument were separated by an arc of 2v, here
that constant arc is of length 2 {u v); so, while there we had
for cn V, and ^—j—- for dn v, here we shall have
R ci
R (X
- — cn (u v), and
R-
— dn{u v).
R + a'
Let S be the middle point of the chord PJ', and T its point of
contact with the interior circle; draw CS and c'T, which will be
perpendicular to fJ', and CI parallel thereto.
Now as J'P = 2<p -\- 24', the angle SCJ' — <p + 4>-, and if from
this be taken ACJ' or 24, the remainder, ACS, is f — 4-_ Now
c'T is r', but
80
Colorado College Studies.
c'T = c'l + IT, ^ c'l + OS.
c'l = a' cos — </') and OS — R cos {(f> + <^');
r' = a'(cos^«> cos^A + sin^c sin9'') + ^(cos^^> cosv'' — sinf sin^'O)
= (i? + a') cos<p cos <l> — (-R — a') sin f sin<l'-
r' , R—a' . . ,
— COS 9 COS (/' — j—y Sin <P sin 4'-
R-\- a R-\- a
But <p and 4' are the amplitudes of u and v, whence,—comparing
equation (29),—
cn {u -\- v) — cnu cnv — snu snv dn (u + v).
Now a similar formula, containing functions of — r, may
of course be obtained in like manner, using an interior circle
that is tangent to PJ instead of to PJ'. And when the two are
combined in one statement, we have
cn{u ± v) = cnu cnv ^ snu snv dn {u ± r). (30
This is the so-called "Formula of Lagrange." From it is
derived directly
, , , cnu cnv — cn(u±v)
dniu ± v) = ^ ,
^ ± snu snv
and thence, by substituting the value of cn (u ± v), as pre¬
viously found,
, , . dnu dnv snu snv cnu cnv
dn{u ±v)= = —5 (31
1 — AT sn'u sn-v ^
It has already been noticed that when any argument u is
inc reased by 2nK, the corresponding amplitude v is increased
by mt. Moreover, when u = 0, then also ^ — 0. And since the
elliptic functions of u are defined by trigonometric functions
ol. (f, it is at once evident that since the latter have a jieriod of
2-, the elliptic functions must correspondingly repeat them¬
selves in periods of 4JI. These inferences may be tested by the
addition formulae just derived, and in particular it may be shown
that dn u has in fact the shorter period 2K.
I wish to indicate in a single paragraph, by way of appendix,
how easily the definitions and formulae of the present paper
The Elliptic Functions Defined.
81
may lie connected -with the methods of the calculus, and also
the character of the assumption which has to be made, in order
to give to the circle of the argument its appropriate relative
magnitude, i. e., to fix the value of K.
By subtracting, one „from the other, the two formulae in¬
cluded in equation (27) we have
/ , s , . 2sn V cn u dn u
sn (u "b V) — sn (u — v) = -z: —5 5- .
1 — fc- sn u S7i'v
Let us replace u by ic -f and v by \h, and then divide each
side of the equation by h-, and we obtain
sn (tv h) — sn w 2sn (ih) cntiu + ih) dn(w -{■ ih)
h ~ [ 1 — sn' {w + ^h) sn' ] h
_ cn [w ^h) dn {iv -|- \h) sn(^h)
1 — Jc^sn\w-]-^h) sn'^(^h) '
"We have here separated the result into two factors. When
h is made to approach zero, the denominator of the first factor
approaches unity, because the second term of that denominator
contdiins the vanishing factor sn^{^h). The numerator of the same
factor approaches cn tv dn tv. But in the second factor we have
the ratio of the chord of a small arc of the circle of the ampli¬
tude divided by the corresponding arc in the circle of the argu¬
ment. That this factor may approach unity as h approaches
zero, it is necessary that corresponding arcs, measured from the
origins in the two circles, shall approach equality as their length
is diminished. Or if corresponding arcs are traced simultane¬
ously by two points, one on each circle, these points must set
out from the origins with equal initial velocities. This condi¬
tion will determine the relative magnitude of the circles; and
when it is fulfilled, the limit, for /!. = 0, of ^
is cn tv dn tv.
ON TWO PASSAGES IN THE CRITO.
BY H. W. MAGOUN.
-^2. Zy.n-uj;iEv, w xa{ el Tivj dvTiXeyecv i/iou
A^^ovtot, dyrc'^eye^ y.ai aoi TzeiaoiJ-ai" ei os //3j, -autrai Tjdrj, u> ;j.axd/jte^
TZoDAy.iz IJ-oi liy(ov Tov abzuv Xuyav^ <0? xpij ivdivoe dxdyztuv 'A{^ryyaiu)V
ifxe diziiyai" <u? iyoj ■Kep\ nolXoo Tzuioopat Ttelaai ae raura npazzeiy^ dkXd
p-q clxoyzoq.
The above passage occurs in the C r i t o of Plato, 48 D. and
E. The works -eicrat ae, near the end, seem to have proved a
veritable crux to the grammarians and the opinions concerning
them have been various. They are spoken by Socrates in his
argument with Crito, in which he tries to show him the fallacy of
urging an escape from the prison, to avoid the fatal hemlock, so
soon to be administered to himself in accordance with the sen¬
tence pronounced against him by the Athenians. A brief review
of the various views held, so far as the limited library resources
at my command has supplied them, will be stated first, after
which will be given what seems to me to be the meaning of the
passage.
The MSS. without exception, so far as I can discover, read
as above, -Keiaai ae. . . . Schleiermacher, Stallbaum, Elber-
ling, and many other commentators have adopted this reading,
taken as as the subject of Tzs'iaai, supplied ipi as its object, and
understood ipou with dxoyzo<;. . . . Jowett evidently agrees
with this, since he renders; "for I am extremely desirous to be
persuaded by you, but not against my own better judgment."
. . . Bekker and some others take as as the object of rstaai
and supply aou with«zovto?, rendering: "As I esteem it of great
importance to persuade you to do this, but not to do it against
On Two Passages in the Crito.
83:
your will." . . . W. S. Tyler, Professor of Greek at Amherst,
in his edition of 1876, adopts this rendering and explains it to
mean; "I am exceedingly desirous to pursue the course T am
pursuing icith ypur consent and not against your wilV In a
later edition, which was prepared with the assistance of Pro¬
fessor H. M. Tyler, he reads -siaaq <72, in accordance with the
emendation given just below, and renders: "As I esteem it of
great importance to do this tvith your consent." . . . Butt-
mann amended to TrstVa? as and the emendation has been accepted
by a number of scholars. The meaning, of course, being that
just given. . . . Goebel suggests that the reading should be
-Muaai as, ' I am anxious to stop you,' i. e., from bringing forward
the same old arguments. . . . Meiser proposes a change of
order; r.s'iaai as, a.X)A (j.rj axoyrog raura -jjazzew. . . . Professor
Dyer, of Harvard, in his edition based on that of Cron, adopts
the emendation of Buttman as Tyler does in his latter edition.
. "Wagner reads Tzsiaaz, "with your approval," and puts
it as antithetical with axox-oq, "without your approval."
Before considering these various renderings it may be well
to have the rest of the passage translated that the meaning of
the whole may be before us. Jowett's rendering, which with
the exception of the last clause, can hardly be improved upon,
is as follows: "Let us consider the matter together, and do
you either refute me if you can, and I will be convinced; or else
cease, my dear friend, from repeating to me that I ought to
escape against the wishes of the Athenians: for" etc., as above.
The position of Schleiermacker, which is followed by Jowett
and others, is met by Professor W. S. Tyler in his old edition,
where he says: " But besides the improbability of r.sXaai being
followed by its subject, and omitting its object, it does not
accord with the sentiments and character of Socrates that he
should say, I deem«it of great importance that you should per¬
suade me to leave the prison, which would then be the meaning:
of the passage." This may be regarded as a sufl&cient answer
to this rendering. . . . The emendation of Buttmann may
Colorado College Studies.
be considered next. It is evidently intended, as is brought out
by Wagner, to make the two expressions, izdaa- and azovrot anti¬
thetical, as though the craze for antithesis which reaches its
akme in Isocrates had actually taken possession of plain and
rugged Socrates who was by no means in the habit of amplify¬
ing a statement for the sake of making it well balanced. Leav¬
ing out of the question the harshness of the three sigmas in the
emendation, rstVa? <ts, which is alone sufficient to condemn it
from a Greek standpoint, the question remains as to what he is
anxious to do when, according to the emendation, he says, in the
words of Tyler, " I esteem it of great importance to do this with
your consent." Kemain in the prison, say the commentators.
Then in accordance with Greek usage, we may expect to find a
.statement to that effect in the context imfUediately preceding;
but Socrates has nowhere uttered any such sentiment nor is it
at all likely that he would say that he was anxious to stay there.
The meaning of the rab-a must be looked for in the context, not
explained by dragging in some outside idea. On this basis,
according to the emendation, Socrates would say: I am exceed¬
ingly anxious to do this, i. e., examine this question with you
(<7zo7rco/iev . . . xoo/fj), if you are willing. . . . Taking
now the MS. reading, which is followed by Bekker and some
others, and looking for the explanation of raura in the context,
the passage means, not as Tyler explains it in his old edition,
" I am exceedingly desirous to pursue the course I am pursuing;"
but 'I am exceedingly desirous to induce you to do this,' i. e.,
refute me (avrlXsys) if you can (e" -rj exstz dvTtki^siv) or else stop
(TraDo-ai) bringing forward the same old argument (tov abrov
but I do not wish to force it upon you' (^dXM fiij dxuvrog).
This is evidently the underlying thought in Goebel's emenda¬
tion to -abaat which is, however, hardly tenable on other grounds,
and the meaning still remains the same in Meiser's proposed
change of order, which is unnecessary. This meaning tallies
exactly with what has preceded and with all that follows. His
whole object and aim has been to do just this, namely to force
On Two Passages in the Crito.
85
Orito to either take new ground or let him alone. In his own
mind, o£ course, the latter is the real goal and Tyler evidently
recognized this in his explanation of the MS. reading; but it is
only an inference from the whole passage, not a meaning to be
taken directly from the Greek; indeed that this was his real
aim become clear only as the argument proceeds. Every doubt
of his object vanishes when the last words of the dialogue are
reached, in which he tells Crito that the voice which hums in
his ears prevents him from hearing any other and that it will
be useless for him to say anything more.
ob S-tj bTtoXoyi'^&aHai. our si airoi'frjffxsiv bsT vapajjiivovra^ xac
^(Toxtay ayoyrag, oure a?.Ao (jTCouy Trda^scy tzpb too ddtxstv.
This passage occurs in 48 D, just above the one already con¬
sidered. Most of the editors with Stallbaum place a comma
after ayovTa? which has the effect of making -pb rob ddusiy depend
upon ;raff;5£!v. Some of the recent editors omit the comma and
thus allow the T:pb rob ddusiy to go back in thought to the bizo^
koyi^?ff9ac where it logically belongs as can readily be seen from
the context. The burden of his entire argument is that they
must consider first the question as to whether they are doing
right or wrong and everything else must give way to this. "We
have here then, as often in Plato, a condensed expression such
as is quite characteristic of Socrates who seems to delight in
" cutting across lots." It stands for something like this; prj
ob ditj brzokoyiZ^a&ai obr si dTsoftT^axsiv dec icapapivovraz xa) ^ffoxc'ay
dyoyra? obrs dkko ortobv Kaa^ety npb rob u-KokoyiZead^at si ddtxsiv dec
5} U-rj.
The commentators, so far as I have been able to consult
them, seem to regard the Tspd rob ddtxscy as depending upon
Tzdao^siv, which involves a logical contradiction, perhaps too subtle
to be noticed by the casual observer; but still a clear logical
contradiction of his position; for it makes his say; " we must
not consider the question, whether we must die, if we remain in
prison and keep quiet, nor whether we must suffer any thing
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else, however dreadful, rather than do wrong," i. e., we must not
consider the question of suffering anything whatever rather
than do wrong, whereas his real position is the exact reverse of
this, namely, we must consider the question of suffering any¬
thing whatever rather than-do wrong and must make up our
minds to suffer anything or everything rather than do wrong.
In effect he puts before Crito this question: Shall we suffer any¬
thing whatever rather than do wrong? and asks him to consider
it with him. His reply to the question is; Yes. While the
commentators give renderings similar to the one cited near the
beginning of this paragraph, they do not seem to realize that
they put the "suffering anything whatever rather than do
wrong" together as a single thought and then make Socrates
say that it must not be considered; for they all agree that the
passage means as Tyler puts it, " we must not take the conse¬
quences into the account at all, but only the question of right
and wrong."* That this is the meaning there can be no shadow
of a doubt; but how to get it without carrying the -po mu dScxiiv
back to the u-uloyi'leadai, which none of them seem to do in their
translations certainly, is a puzzle. That this is its real depend¬
ence and that the sentence is a condensed one for something
like the expanded form suggested above seems very likely,
since it removes every difficulty in the way of a clear under¬
standing of the passage, f
* Jowett dodges the diflSculty while giving the sense perfectly. He
renders : " and if the latter [if we shall do rightly in escaping], then
death or any other calamity which may ensue on my remaining here
must not be allowed to enter into the calculation."
jCf. the similar passage, A p o 1 o g y, 28 D.; iv-avda 6u, of ipol doKd
fihovra KivSvveheiv, /u/Kv VTroXoyiCb/xevov fit/re -davarov pi/re aA'Ao pr/div irph rov aia-
jcpov.
THE CALIBRATION OF BURETTES.
BY DOUGLAS CARNEGIE.
The balance is the supreme tribunal of the chemist. No
matter how simple and brief, or how complicated and pro¬
longed, a chemical operation may be, its alpha and omega is a
weighing.
Oftentimes, however, the conditions of the investigation are
such that direct weighing cannot be carried out with the
exactitude demanded. In such cases, recourse is had to a
method of indirect weighing which I venture to call volumetric
weighing.
It is the object of this note to show how this volumetric
weighing may be carried out with accuracy.
Suppose that we wish to ascertain the exact quantity of sil¬
ver nitrate that is necessary to completely precipitate 1 gramme
of common salt in a solution colored yellow by potassium chro-
mate. It is well known that if we add the silver nitrate in small
quantities to such a solution, the latter will finally change from
yellow to red, when just a little more silver nitrate has been
added than is necessary to precipitate the whole of the salt.
Suppose that in this investigation we add the silver nitrate in
small pinches from a quantity originally weighed, and that as
soon as the color change appears we weigh the quantity of sil¬
ver salt remaining. It is obvious from what precedes that the
quantity of silver nitrate thus deduced will be two great by a
pinch, or some fraTition of a pinch. If the average weight of
the pinches was, say, 1 m. g.: and the whole experiment turns
on rsVifth of this quantity, it is clear that the investigation does
not lend itself to a method involving direct weighings.
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The recipes of chemistry are not like those of the cuisine;
the latter deal with a palate which is insensible between cer¬
tain wide limits—the range embraced between the extremes
" too salt," and " not salt enough," being a fairly wide one, and
easily hit ofip. But the recipes of chemistry have to do with
indicators which are so fastidious that there is always either too
much or too little salt for their taste; and the object of indirect
or volumetric weighing, is to give them a little too much salt,
but at the same time to contrive that the excess is infinitesimal
in comparison M'ith the degree of accuracy aimed at.
If a known weight tcof silver nitrate be dissolved in a known
volume (a litre, say) of water, so that one drop of the solution
contains m. g. of dissolved silver salt, then it is clear that by
adding such a solution, drop by drop, from a burette to the com¬
mon salt solution, a very much more accurate and quicker result
will be obtained than by the first procedure. If x c. c. of the
silver solution, as read off from the burette graduations, have
been used, then we know that 1 gramme of salt requires
exactly grs. of silver nitrate to precipitate it, 'provided only
that the graducdions of the burette used to measure both the
X c. c. and the litre are consistent among themselves. The
determination whether or no this is the case constitutes the
" calibration of the burette."
The method of calibration given in all text books is roughly
as follows. The burette is filled with water, and successive
portions, corresponding to 5 c. c. or so, are run out into dry
beakers. From the weights of these successive portions a table
of corrections can easily be deduced. This method in the case
of an ordinary 50 c. c. burette and with 5 c. c. tests, involves at
least 11 weighings and 10 level-readings.
The method of calibration 1 would suggest is, 1 believe,
more accurate than the above, and involves no weighing what¬
ever; for it is quite a matter of indifference to the chemist,
whose measurements are all relative, whether he adopts as his
unit the true cubic centimetre, or an arbitrary one.
The Calibration of Burettes.
89
The principle of the method consists in causing a constant
Tolume of liquid to slide in the burette (so that it may be
made to assume any desired position therein) and then reading
ofiP its length in terms of the burette divisions.-
In Fig. 1 the burette B is attached by means of caoutchouc
tubing C, to a reservoir R, which is filled with
water, and which can easily be raised or low- «
ered by sliding the clamp K along S. On
the surface of the water in the burette there
is a small column of carbon bisulphide W, ®
which obviously, can be made to assume any I » r
desired position in the burette by either
raising or lowering R, and then turning the
stop-cock n very gently.
In my first experiments I used mercury
in place of water in R, and water in place of
carbon bisulphide as a movable index. But ^
this combination was unsatisfactory; I found
it exceedingly diflBcult to read the level I,
both on account of the convexity of the mer-
cury surface, and also on account of the
peculiarly disturbing light refiexion from the
bounding water-mercury surface.
The combination, water and carbon bisul¬
phide works admirably if the following precautions be taken.
The burettemust be thoroughly cleaned txom grease and dust
before calibration. The resevoir R is then filled with freshly
distilled water, and matters are so arranged that the level of the
water stands at g, the lowest graduation of the burette. A long
thistle funnel is then inserted into the burette, and a small
quantity (say 5c. c.) of recently distilled CS^ is poured gently on
the surface of th^water. Under these circumstances the CS^, in
spite of its higher specific gravity, floats on the water, and
exhibits two easily localized concave meniscuses. It is well to
shake the CS^ up with distilled water, so as to thoroughly satur-
7
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ate it, and to tint it slightly with iodine before pouring it into
the burette.
The method of procedure is obvious. I will merely add that
in altering the position of the CS2 index, it is well to let it rise
a little higher in the burette than the required graduation, and
then lower it by careful manipulation of the stop-cock n. The
burette should, of course, be kept stoppered as much as possi¬
ble during the calibration.
I would also particularly emphasize the fact that the method
works satisfactorily only when the calibration is effected as
describ^d—from below, upwards.
The readings obtained can be used for calibration as
described in detail in Bunsen's " Gasometry."
In order to avoid errors of parallax in reading off the levels
of the CS2 column, I silver a strip on the back of the burette
This mirror strip, which does away with all floats and similar
devices for avoiding errors of parallax in the subsequent use of
the burette, is easily made as follows. The burette having been
thoroughly cleaned externally, is corked air¬
tight, and then inverted in a tall cylinder con¬
taining an alkaline silvering fluid* After
some time it is withdrawn and allowed to
become ihoroiighly air-dried. The silver can
then be easily removed from the front and
sides by scraping, followed by a final rubbing with a rag moist-
.ened with dilute nitric acid. The slip of silver backing the
burette is then fixed by one or two coats of varnish.
In reading such a burette it will be found advantageous to
look at the meniscus through a slit cut in a sheet of white
glazed paper, held at an angle to the vertical as shown in Fig.
ii. The burette graduations are also rendered very much more
distinct by rubbing the front of the burette^rst with apiece of
flannel on which a paste of turpentine and mercuric iodide has
been placed, and then with a dry cloth.
* Suitable fluids are described in Roscoe & Schorlenimer's Treatise on Chemistry
"Vol. II ., part I., p. 363.
z
ON A PASSAGE IN THE FROGS.
BY H. W. MAGOUN.
In the Frogs of Aristophanes in a speech of Dionysus,
line 268, occur the words;
( sfieXXov apa T:au<Tstv rou xod^,
'I thought I should make you stop your croaking sometime.'
The passage seems to have troubled some of the commentators,
notably Fritzsche who thinks that the commentators as a whole
have quite failed to understand the passage. He takes it in per¬
fect seriousness and supposes that Dionysus must mean all that
he says.
He infers from line 257,
oipai^er" od yap pot pikei^
' Go howl; for I don't care a fig,' which he renders ' be cudgeled,'
{vopulate) etc., that Dionysus takes his oar and beats the frogs;
but he fails to explain what Charon was doing all this time that
he allowed such proceedings, or how the boat could come to laud
with one oar only in use for rowing. The simple fact is that
Dionysus is merely an overgrown boy in his actions and words,
in fact a kind of clown almost, and he must be judged on this
basis. The Greeks as a whole were "but children of a large
growth" at this time, and in their comedies especially were like
a crowd of boys. The frogs began their croaking only when
Dionysus embarked and began to row, lines 206-7,
^dxootret yap pikr)
xdXkiar^ ineiddv Ip^dXrj^ ana^.
It is natural then to expect them to stop when he ceases rowing
as the boat comes to land. This is exactly what happens and
Dionysus, who has been bawling at them to stop their noise, in
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true boyish fashion now takes all the credit of their silence to
himself. It may be added that Charon had told him that the
singing would make his rowing easy, line 206, ar- dxoOast etc.,
as above, although he was, as he himself said, a land-lubber,
d'^ai.dTT£UTO(;, line 204 Human nature is all that is needed to
explain the passage, or more accurately youthful nature indulg¬
ing itself in boyish pranks and words.
A NOTE ON THE HADLEY-ALLEN GRAMMAR
By H. W. Magoun.
While Professor Allen has made an excellent revision of
Hadley's Greek Grammar, it has happened in a few instances
that the improvement intended has failed to be realized. Such
a case appears in § 199, where he says of feminines in -ai of the
third declension: " These stems seem to have formerly ended
in -of-I : hence the voc. sing, in -oi an older form of the nom.
in -u> : luTtfu." This explanation might help to make clear the
voc. sing., which in the third declension is prevailingly like the
stem; but it must fail to account for the nom., since the ques¬
tion arises at once how it happens that the nom. did not take
the regular ending precisely as other iota-stems do, such as
T:6kt-<;, d(>vap.:-(;, etc., which it will be observed are also feminines,
and it further produces the grave difficulty of accounting for
the dropping of both the digamma and the iota in the oblique
cases where such a stem ought to give us a diphthong -oT-. It
seems very likely that the real explanation may be found in
supposing that these are really " yod"-stemsi that is, that the
real final letter is the so-called iota which appears under a
changed form in the so-called iota class of Greek Verbs, where
the old Greek -iw appears in Sanskrit as -yd-. If this is the
case, it may be possible to explain the whole paradigm. In the
oblique cases this " yod " simply dropped, exactly as it did in
Tjoe??,* Sanskrit trdy-as, and contraction took place precisely as
*See Brugmann, Grundriss der Vergleichenden Grammatik der
Indogermanischen Spraehen, Erster Band, §§129 and 130 Of. also §§ 117>
118, 119, etc. For verb forms see Muller's Handhuch der Klassisehen
Altertums-Wissenschaft, Zwelter Band, §§ 123 and 124.
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in similar cases. For the voc. the following equation may be
ventured upon:
Voc. aaiztfoX : stem of aa-^'th : : voc. -j3od : stem of pou-<;
that is, in each case the stem form is used for the voc. according
to the regular rule; but the final elements (digamma* and
" yod") are forced to pass into the corresponding vowels and
so become part of a diphthong by the Greek law which prevents
any consonant from being final, save v, p, ?. This rule is plain
for the digamma: it may not be so clear for the "yod," as will
be shown below. However, analogy is quite sufficient to estab¬
lish the equation and make this explanation hold good. The
accent in both cases can be readily accounted for by the well-
known Indogermanic law that the accent of vocatives is reces-
sive.f The nom. remains te be accounted for. Professor Allen
mentions the fact that the old form ended in -w. That this was
the original form has been made clear by certain inscriptions,
for example, those of the Corinthian dialect, of which a few
have been found. In these inscriptions names of women
appear in the nom., ending, as Cauer J writes them in -6 with t-
subscript, which means of course that they were written in the
old alphabet and ended in 01. Just here it may be noted that
all other nouns of the third declension in Greek, except neuters,
end in a consonant, either the regular ending -? or the final
consonant of the stem with a lengthening of the stem vowel.
If, then, the final iota of these old nominatives can be shown to
be a " yod " or y, the form is a perfectly normal one ending in
the consonant of the stem with the regular vowel lengthening
to -u)-. This would account for the missing -? and make the form
* That the stem of pov-^ is fiof-, in spite of Sanskrit gdu-s, appears
from Lat. ho-s, gen. bov-is. Cf. Mailer's Handbuch, Zweiter Band § 24'.
The fact that the dialects show lepvi for Upevc may be taken as evidence
that ^aailevQ, etc., ought also possibly to be classed as digamma stems.
See Gustav Meyer, Qriechische Grrammatik, Zweite Auflage, § 323.
t See American Journal of Philology, Vol. IX, p. 16, Bloomfield, The
Recessive Accent in Greek.
t See Cauer, Pelectus Inscriptionum Grcecarum, p. 52.
Note on the Handley-Allen Orammar.
95
plain. Later on, when -««! became -v in dative forms, etc., this
"yod" would naturally drop altogether; for, while graphically
the two endings were the same, phonetically they may be repre¬
sented as follows:
Final -(i)l of final -wt of dat. oHuj ; : final 01 of olxoi : final
of <nxot.
That is, the final letter of Ia-4>w is probably the weaker of the
two,* being about equivalent to an English -y, while in the
second case the -t is really a vowel. This explanation is sug¬
gested merely as a possible one which seems to meet the pecular
difficulties of the case. These nouns were treated a few years
ago in one of the German periodicals; but the writer of this
note has never seen the article and it is not at present available.
It only remains to be said that while such nouns as Sanskrit
s6nd, voc. s6ne may throw some light on these formations, it
seems rather doubtful on the whole.
* See American Journal of Philoloyy, IX, 25. If it be true that the
final -Ot of oiKoi is really -03', the reason for its being short in determining
accent becomes clear at once. Moreover, in such lines as Horn. II.
B. 136
at (5f nov yfieTcpai r' d?MXOC Kal vr/TTta TtKva
it will not be necessary to fall back upon the ictus as a reason for the
long final -at'? and-ot; but the final -t plus the following consonant being
equal to -y plus a consonant will make position and so cause a long
syllable.
HISTORICAL NOTE ON THE DIFFERENTIATION OF A
LOGARITHM.
BY FLOKIAN CAJOEI.
The preface of Olney's Calculus contains the following pass¬
age: "In conclusion I must do myself the pleasure to acknowl¬
edge my indebtedness to my accomplished colleague and friend,
Prof. J. C. Watson, Ph. D., for the original, direct, and simple
method for demonstrating the rule for differentiating a logar¬
ithm .... which banishes from the Calculus the last
necessity for resort to series to establish any of its fundamental
operations" Statements to this effect are also found in a few
more recent American works on the Calculus.
Dr. E. W. Davis has called my attention to the fact that a
method of proving the rule for differentiating logarithmic
expressions without resorting to infinite series is given in De
Morgan's Calculus. I see that such a method is found also in
John Eowe's "Introduction to the Doctrine of Fluxions,"
Fourth Edition, London, 1809. The first edition was printed in
1751. Doubtless other old books with similar methods of
demonstration which do not involve infinite series can be found.
The credit of first banishing from the Calculus " the last neces¬
sity of resort to series to establish any of its fundamental oper¬
ations " can, therefore, not be ascribed to Watson.
A MATHEMATICAL ERROR IN THE CENTURY
DICTIONARY.
BY FLORIAN CAJOEI.
The Century Dictionary, under the head of "Logarithm,"
gives a table in which are found the two left hand columns of
numbers given below. The second column is wrong, all the
numbers being too small by 61180956. The relation between
Napier's and natural logarithms is expressed by the well-
known formula,
logjv « = 10' ^ •
Calculating by this formula the logarithms of .1, 1, etc., we get
the numbers in the columns on the right, which are the true
Napier's logarithms. Napier's original publication, the Descrip-
tio canonis of 1614, contained only logarithms of sines. The
logarithms of the particular numbers given below can therefore
not be found in the table. But by our formula we are able to
reproduce the logarithms in Napier's tables, and we are, there¬
fore, sure that our calculated logarithmic figures in the column
on the right are correct. For example, the sine of 44° 19' is
given in Napier's table as 6986235 and its logarithm, 8586432.
Quite the same logarithm is obtained by calculation by our
formula. Again, the Century Dictionary gives a minus logar¬
ithm for 10\ while Napier's logarithms of all numbers below
10' are positive.
Natural Napier's Logarithms, The true Napier's
Numbers as given in 0. D. Logarithms.
0.1 123025851 184206807
1 100000000 161180956
IP 76974149 138155105
100 53948298 115129254
1000 30922447 92103403
10000 7896596 69077552
100000 —15129255 46051701
qOliOl^i^L)© (^OLitiEGE
V^lorado 5prii}$S, Qolo.
*
I
The College offers two courses, leading, respectively, to the degrees
•of Bachelor of Arts and Bachelor of Philosophy. In the Ph. B. Course,
Greek is omitted and more attention is given to the science, and modern
languages. The College has a good library and well equipped labora¬
tories.
The various courses of study have now been so arranged and the
faculty so enlarged that Colorado College offers the same educational
facilities as the Eastern Colleges. For catalogues, address
WILLIAM F. SLOCUM, Pees.
The Cutler Academy,
Under the auspices of the Colorado College, gives students a thorough
preperation for admission to the Freshman class of any college in the
country. Correspondence concerning the Cutler Academy should be
addressed to the Assistant Principal,
GEORGE L. HENDRICKSON.
The location of the College is unsurpassed. Col¬
orado Springs has a ivorld-ivide
reputation as a
Students forced by pulmonary or malarial troubles to discontinue
their studies in*the East, pursue college courses here successfully and
at the same time make a permanent gain in health. A recent number
of the Colorado School Journal speaks of this college town in the follow¬
ing words:" No point in our State ever combined as many advantages for
the establishment, growth and greatness of a college as does Colorado
Springs: It is manifestly the point about which scholars and students,
men and women of culture, wealth, and leisure will reasonably gather."
THIRD ANNUAL PUBLICATION.
Colorado College
h
Studies.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLO.
1892.
THIRD ANNUAL PUBLICATION.
Colorado College
Studies.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLO.
1892.
Slil
CT\^
t
v/,3-
Officers, 1892.
President, William Stuieby
Vice-Presidents, . Dr. A. T. Murray and Dr. W. P. Mustard
Secretary, Florian Cajori
Treasurer, Frank H. Loud
PLACE OF MEETING,
Palmer Hall, Colorado College
Table of Contents.
page
The Etymologies in the Servian Commentary to Vergil, .... 1
Dr. W. p. Mdstard.
Notes on Jefferson's Draft of the Ordinance of 1784, 38
W. M. Hall.
Some Notes on Blaydes' Nubes, 42
Dr. a. T. Murray.
On a Passage in Euripides' Iphigenia Taurica, 50
Dr. a. T. Murray.
Draper's Barograph, 52
Florian Cajori.
The Conditional in German, .55
Dr. S. Primer.
ANNOUNCEMENT.
The Colorado College Scientific Society has entered upon
the third year of its existence, and hereby issues its third
annual publication. It is the intention of the Society to in¬
clude in the publication for next year meteorological records
obtained from self-registering instruments in the Physical
Laboratory of Colorado College.
The following is a complete list of the papers read at the
monthly meetings of the Society during the past year. Sev¬
eral of the papers are printed in full in this pamphlet, while
others have been or will be published elsewhere.
October 13, 1891—
The German Conditional, Dr. Sylvester Primer.
Historical Sketch of the Study of Mathe¬
matics in the United States (published
in Bibliotheca Mathematica, No. 3,
1891, Stockholm, Sweden) .... Florian Cajori.
November 10, 1891—
Notes on Jefferson's Draft of the Ordinance
of 1784, W. M. Hall, ,
The Delphin Classics Dr. W. P. Mustard.
December .5,1891—
Dust, Douglas J. Carnegie.
The Australian Ballot System, . . W. M. Hall.
January 19,1892—
A Review of Weissman's Theory of He¬
redity, Pres. Wm. F. Slocum.
February 15,1892—
Some Notes on Blaydes' Nubes, Dr. A. T. Murray.
Helmholtz's and Koenig's Theories of Har¬
mony, Douglas J. Carnegie.
March 29, 1892—
Cold Winds of the Plains (Extract from a
Paper prepared for the U. S. Weather
Bureau), Frank H. Loud.
Multiplication of Series (published in the
Bulletin of the N. Y. Mathematical
Society), Florian Cajori.
Draper's Barograph, Florian Cajori.
April 26,1892—
Hypnotism, Marion M. Noyes.
The Detection of Gas Leakage in House
Plumbing, William Strieby.
On a Passage in Euripides' Iphigenia
Taurica, Dr. A. T. Murray.
The Etymologies in the Servian Com¬
mentary to Vergil Dr. W. P. Mustard.
May 16, 1892—
The Rise of the New Psychology, . . F. R. Hastings.
Actinomycosis or Lumpy Jaw, . H. C. Crouch, M. D.
The Evolution of Criteria of Convergency
(to be published in the Bulletin of the «
N. Y. Mathematical Society), . . . Florian Cajori.
THE ETYMOLOGIES IN THE SERVIAN COMMENTARY
TO VERGIL.
By- WILFEED P. MUSTABD.
I.—Servius the Etymologist.
The Roman philologists, from Aelius Stilo down,were much
given to etymologizing. Some interesting specimens of early
effort in this line are cited by Quintilian, Inst. or. I 6, 32-38,
where some of the results of the principles recognized and
employed by his predecessors are characterized in the words
Hnde pravis ingeniis ad foedissima usque ludibria labuntur.'
The vast number of etymological notes in the commentary to
Vergil shows what a charm this fascinating study had for the
grammarians of a later day.* In one or two points Servius
shows a distinct improvement upon the methods of his prede¬
cessors, but he has not escaped all the faults of his age.
His character as an etymologist may be inferred from the
following summary.
I. He makes free use of the principle that objects may be
named from their contraries, xar av-itppaav^, applying it to
the explanation of the following words: ardea, A. 7, 412;
helium, A. 1,22; Charon, A. 6,299; Eumenides, A. 3,63; 6,250;
6, 375; G. 1, 278; lucus, A. 1, 22; 1, 441; lustrum, A. 1, 607;
mactare, A. 4,57; manes, A. 1, 139; 3, 63; Parcae, A. 1, 22; G.
1, 278. This convenient principle, which Voss in his Ety-
mologicon, v. lucus] called 'inane Orammaticorum commen-
tum,^ had long been employed by the Greeks. Thsrt it was
recognized from an early period at Rome is evident from
Paulus, p. 88t: Militem Aelius a mollitia y-ara wj-i<pftaaiv
* Servius offers or quotes etymologies for almost a thousand words,
t Beferences to Festus and Paulus in this paper are to the pages of Ponor's edition, 1889.
2
Colorado College Studies.
dictum indat, eo, quod nihil molle, sed potius asperum quid
gerat.
II. He is very fond of deriving Latin words from Greek.
On Aen. 1, 181, he says: Sciendum autem est etiam Latina
nomina Graecam pleruijique etymologiam recipere. Natu¬
rally enough he goes to an extreme in this direction, and we
find him offering a Greek etymology not only to Latin words,
which are at most cognate with Greek, but to others where
the connection he assumes is absolutely wrong. A few ex¬
amples will suffice to show some of the results of this ten¬
dency.* animus, A. 1,57, and anima, A. 8,403, rwv aviimtv.
antes, G. 2, 417, a-o rou dvTKrrij'zsiv. aptum, A. 4, 482; II, 202,
di:d TOI) a-TsaOai. ars, A. 5, 705,d-d rrj'S dpsr^?. inclita, A. 6, 781,
Graecum est; nam xXurdv gloriosum dicunt. ara, A. 2, 515, a
precibus, quas Graeci dpd? dicunt. rura, A. 1,430, Graece apoupa
dicuntur. Aphaeresis ergo sermonem fecit Latinum. telum,
A. 2, 468; 8, 249; 9,507; 9,744, drd too rrpj)0ev. ulna, B. 3,105,
d-rro Tciv wXsvaiv. ululae, B. 8, 55, d;rd zou 6ku?.6!^£tv. uri, G.2, 374,
drco zmv dpiwv. Frequently we have two or more derivations
offered for the same word, and in several cases one of these
optional etymologies is from the Greek. For examples see
the explanations of Acidalia, A. 1, 720; ancile, A. 8,664; annus,
A. 1, 269; clarigatio, A. 10,14; Quirinus, A. 1, 292; scopulus,
A. I, 45; Vesta, A. 1, 292.
Nettleship, Lectures and Essays, p. 212, notices a remark¬
able difference between Varro and Verrius Flaccus in the
matter of etymology. Varro, if we may judge by the De
Lingua Latina, preferred to explain Latin words by assuming
for them a Latin origin: Verrius, to judge from the epitome
of Paulus, certainly seems to have a predilection for deriving
Latin words from Greek. Possibly Servius" fondness for
Cfraecizing etymologies is one of the results of his indebted¬
ness, direct or indirect, to Verrius'' great work.
III. The Roman philologists usually confined their in¬
quiries very strictly to their own and the Greek language,
paying little attention to other languages or even to the
•All quotations from Servius in this paper are from the edition of Thilo and Hagen,
187S-1887.
Etymologies.
3
Italian dialects. It may be noted that Servius mentions
not only several Greek words which are not Attic but about
thirty words which are neither Latin nor Greek. These he
assigns to various languages and dialects as follows: Punic:
Bal, A. 1, 729; caesa, A. 1,286; Carthago, A. 1, 366; Dido, A.
4,36; 4, 335, and 4, 674; magar, A. 1,421. Sabine: cupencum,
A. 12, 538; curis, A. 1, 292; dira, A. 3, 235; hernae, A. 7,684;
hirpi, A. 11, 785; Loebasius, G. 1, 17; nar, A. 7, 517. Gallic:
Alpes, A. 4,442; caesar, A. 11, 743; gaesa, A. 7,664; gaesos, A.
8, 660; virga, A. 8, 660; volema, G. 2, 88. Etruscan: arimos,
A. 9, 712; Camillus, A. 11, 558; capys, A. 10, 145; Mantus,
A. 10, 198. Egyptian: Isis, A. 8, 696; BEYO, A. 4, 577.
Macedonian: phalanx, A. 11, 92; sarissa, A. 7, 664. Doric:
'Qptwv, A. 1,535; Paean, A. 7,769. Laconum lingua: tityrus.
Proem, ad Buc. Cretan: smvaihicem, A. 3,108. Phrygian:
sminthos, A. 5,108. Aeolic: fftous, A. 3,445; 6,12. Libyan;
Ammori, A. 4, 196. Assyrian; El, A. 1,642. Persian: g&za,
A. 1, 119; 1, 359. Oscan: Lucetius, A. 9, 567. Umbrian:
dira, A. 3, 235. Tyrian: sar, G. 2, 506. Illyrian: Varro, A.
11, 743. Lingua Theotisca: cateia, A. 7, 741.
IV. Servius distinctly forbids the derivation of Greek
words from Latin. On Aen. 11, 31 (Parrhasio), and G. 2, 4
(Lenaeus ) he says' nam Graecum nomen etymologiam Latinam
non recipit,' in each case rejecting the explanation of Donatus.
And yet we find him deriving castor, G. 1, 58, 'a castrando';
pausia, G. 2, 86, 'a paviendo'; tus, G. 1, 57, 'a tundendo'.
V. He lays down the important rule that a word should
agree in quantity with the word from which it is derived.
This principle is emphasized several times: Aen. 1, 498,
(Diana); A. 1, 535 (Orion); A. 1, 185 (totus); A. 1, 726
(lucerna); A. 2, 557 (litus); A.8, 51 (Pallanteum). On Aen.
1, 726, e. g., he says: "a lychno autem lucerna dicta est, unde
et brevis est 'In' . . . , si enim a luce diceretur, non staret
versus." On Aen. 2, 557 he rejects the derivation of 'litus'
(from 'litare', o« from 'lituus') offered by Donatus—the same
Donatus to whom.he says 'latebat', A. 3, 636, suggested 'late
patebat', and 'exilio', A. 2, 798, seemed a metrical equivalent
for 'ex Ilio'. M.Thomas remarks,E'ssai sur Servius,p. 224,
4
Colorado College Studies.
that Servius himself forgets this rule in explaining ' curulis',
A. 11, 334 ('a curru', sc.). It is not hard to find much more
striking violations of it. There are several passages in which
words of different quantity are connected without comment:
Gr. 2, 97, aminneum (quasi sine minio); A. 6, 4, anchora
[ayxu/ja); A. 8, 190, Cacus (xaxdi); A. 6, 299, Charon (quasi
(\yiujna'x)\ G. 2, 93, defrutum (defraudatur .... fraudem)*;
A. 3,35, Gradivus (gradior)*; A.6,180, cedria (quasi xaioiiivtj^
dfiuu? uyfx'rx)-, B. 4, 35, heroas (terra epo. dicta); A. 1, 292,
securis (quasi semicuris); A. 1, 688; 4, 2, venenum (quod per
venas eat); and the implied etymologies of Acheron, A. 6,
107, (quasi sine gaudio),and irritum, A. 7, 421 (a retibus).
VI. M. Thomas, Essai sur Servius, pp. 208-210, discusses
Servius' attitude towards the fables which proved so attract¬
ive to the grammarians of Quintilian's day (see Inst. or. I 8,
19). Our commentator remarks more than once (on Aen. 6,
74, and 6, 617,) that Vergil, and the poets generally, are apt
to vary the forms of these stories. Frequently he mentions
a fable only to reject it: ad Aen. 3, 73,' Veritas longe alia est';
ad Aen. 6, 134, 'ratio autem haec est'; ad Aen. 2, 7, 'sed hoc
fabulae est'; ad Aen. 6,14, etc. Such stories are always quoted
as fabulous, and are usually prefaced by some such words
as 'fabula autem talis est', yet they prove a convenient re¬
source, especially in Daniel's Scholia, for the explanation of
several words. Accounts of people changed into animals,
birds or plants, of implements named after their inventors,
etc., are given under the following words: aer*;?, A. 1, 394t;
amaracus, A 1, 693; anethus, B. 2, 47; yslmvri, A. 1, 505;
A. 4, 250; circinus, A. 6,14; Sdcpvtj, A. 3, 91; hyacinthus,
•Vergil, G. 4, 269, has defrutum (u s/iorf); Plautu8,P8eudol. II4, 51, defrutum(u long)—
' Murriuam passum defrutum mellam mel quoiuismodi,* (Ussing's reading). Mlnton War¬
ren, Amer. Jouim.of Phil., Vol. IV, p. 73, has found four Instances of Gradivus (a short) out
of fifty-three where the word occurs in Latin poetry. These are Ov. M. 6, 427; Val, Fl. 5,
651; Sil. 15,15; 15,337. In each case Gradivus is at the end of a hexameter.
tin quoting from the Servian commentary I have everywhere distinguished between
the 'vulgate' and the additional notes found in the fuller version. Thus an italicized refer¬
ence such as ad Aen. 4,2o5 means that the note which follows is found only in Daniel's
Scholia; when part of a note is printed in italics as 'Amazon, quasi avSG fia^oOy sine
mamma*, the italicized words are added in the fuller version, the rest is in the vulgate.
Such references as Africa, Aen. 6, 312; 5,128, quasi arsp are meant to imply that
the same or a similar etymology is given in each division.
Etymologies.
5
A. 11, 69; B. 3, 106; lynx, A. 1, 823; myrtus, A. 3, 23; 5, 72;
narcissus, B. 2,47; G. 4,160; olvov, G. 1, 8; palaestra, A. 8,138;
papaver, B. 2, 47; philyra, G. 3, 93; (poXXa, B. 5, 10; aratpuXijv,
G. 1, 8', thorax, A. 9, 503. With the exception of palaestra
(A. 6, 642; G. 2, 531) no other explanation of any of these
words is offered in any part of the commentary.
VII. The phonetic possibilities recognized in Servius'
etymological notes may be grouped as follows;
(a) 'nomina corrupta' or 'aetate corrupta': Arpi, A. 11,
246 (Argyrippa); Casperuli, A. 8, 638 (Caspiri); Crustume-
rium, A. 7, 631 (Clytemestra).
(5) 'in diminutione plerumque multa mutantur': ofella,
A. 6, 420 (offa).
(c) Vowel-changes 'in derivatione': caelata, A. 1,640 (celum
... in derivatione mutatur). There is a similar note on
G. 2, 291 (aesculus ab esu). In two cases, however, the diph¬
thongs apparently presented no diflSculty and the derivations
of Maenala, G. 1, 17 (a;ro t&v firjXwv), and cedria, A. 6, 180
(quasi xaco;iivrj<i dpuu? oypov) are given without comment.
(d) There are seven words distinctly put down for 'per
antistoechon' formations: curculio, G. 1,186 (quasi gurgulio);
laquearium, A. 1, 726 (lacunarium); magalia, A. 1, 421 (ma-
gar); meditor, B. 1, 2 {psXeToi, '1' enim et'd' interdum sibi
invicem cedunt.); Poeni, A. 1, 301 (quasi phoeni); sella, A. 7,
169; B. 1, 2 (quasi sedda); solium, A. 7,169 (quasi sodium a
sedendo).
(e) et amurca per 'c' scribitur et per 'g' pronuntiatur, ut
'C.' Gaius, 'Cn.' Gnaeus. G. 1, 194.
(/) Implied similarity of certain sounds. Tumultus, A.
2, 486; 8, 1, quasi timor multus. Mercurius, A. 8, 138, alii
Mercurium quasi Medicurrium a Latinis dictum volunt.
cadaver, A. 8,264, cadaver est corpus nondum sepultum, dictum
cadaver quod careat honore sepulturae. asylum, Aen. 2, 761,
dictum ' asylum ^qiiasi 'asyrum.'
(g) Synaeresis. saltem,A.4, 327 (salutem. .. persynaere-
sin); conpostus, A. 3, 152 (pro conpositus).
6
CoLOEADO College Studies.
(h) Aphaeresis. A. 1, 430, rura Graece apoupa dicuntur.
aphaeresis ergo sermonem fecit Latinum. With this compare
the following etymologies which are given without comment:
Boaulia, A. 6, 107; 7, 662 (caulam bubus fecit); carceres,
A. 1, 54; 5,145; G. 3,104 (quasi arcer abarcendo); caulae, A.
9,59 (Graecum nomen 'c' detracto); Caulon, A. 3, 553 (Aulon
mons est etc.); cortiiia, A. 3,92 {alii . . . quasiortina . . .
quod inde vox oriatur); Segesta, A. 1, 550 (Egesta); A. 5,
718 (Acestes).
(f) Ehotacism. A 4,219, aras (asas), Valerios (Valesios),
Furios {Fusios), etc.
(/c) Representation of certain Greek sounds in Latin.
i. apricus, A. 5, 128; 6, 312 (quasi arsp <pp(xr^g).
Africa, A. 5, 128; 6, 312 (quasi arsp fpixrj^).
herba, G. 1, 120 {<pop[irj).
ii. Spiritus asper. Formiae, A. 7, 695 (inmutato H in
F . . . aizb TT/? upprji).
Septem, B. 2, 11 (in multis enim nominibus,
quae in Graeco aspirationem habent, nos pro
aspiratione 's' ponimus: inde est . . . pro
hepta 'septem').
aptuA, A. 4, 482; 11, 202 aTiv rod a-xtaOai).
iii. Digamma. Belus, A. 1, 642 (El . . . addita
digammo . . . ).
Velia, A.6,359 (Elia . . . accepit digammon . . .).
In a number of etymologies the recognition of any un¬
usual phonetic possibility is so doubtful that they have not
been included under this head. If Servius derives'Africa'
from aVso (fpixri^ in one part of his commentary, from azsp
<ppixri<s in another, he probably means in each case only 'a
privative.' So with the explanations of 'Amazon' (quasi
uveu pa^ou) and 'apricus' (quasi arep <pptxrj(s). In other notes
'a privative' is indicated by the word 'non' or 'sine': Ache¬
ron, A. 6, 107 (quasi sine gaudio); Alexis, B. 2,1 (quasi sine
responsione); aminneum, G. 2, 97 (quasi sine minio); ato-
mos, B. 6, 31 (quia Topr/v non recipiunt). The 'sine' which
appears in another group of etymologies perhaps means only
'se', although Servius makes no such definite statement on
/
Etymologies. 7
this point as we find in Isidore, or. X 247: segnis, id est sine
igne, ingenio carens. Se autem sine significat, ut sedulus
sine dolo: securus, quasi sine cura, etc. In two other pas¬
sages Isidore omits this explanation: orig. X 244, sedulus fami-
liare verbum Terentii: hoc est sine dolo; orig. X 262, sepultus,
sine pulsu, id est sine motu. Accordingly, when Servius
explains 'securus', A. 2, 374, as 'sine cura\ sedulus, A. 2, 374,
&8'sine dolo', segnis, A. 1, 423; 2, 374, as 'sine igne', and
'sepultus', A. 8, 41; 6, 424, 'quasi sine pulsu', it seems safer
to suppose that he really means 'se dolo', 'se igne', etc., than
to infer that he allows the ' n' of ' sine' to disappear.
VIII. The additional notes of Daniel's Servius are some¬
times supplementary to those of the vulgate, sometimes repe¬
titions of them, sometimes inconsistent with them. Examples
of inconsistency in the matter of etymology may be seen
under the following words*: ara, A. 2, 515; 4, 219; bruma, A.
2, 472; O. 1, 211; feretrum, A. 11, 64; insertas, A. 8, 152;
jubar, A. 4,180; latrones, A. 12, 7; palaestra, A. 6, 642; 8,138;
G. 2, 851; Praeneste, A. 7, 682; vitula, A. 1, 538; B. 8, 30.
One of the chief arguments relied on by Thomas (p. 49)
and Thilo (Praef. XIII) as showing that these 'additional'
notes did not form part of the original commentary of Servius
is the following: the additional notes quote a variety of opin¬
ions upon disputed points without deciding upon any one in
particular, while the vulgate usually does so only to adopt
one in preference to the others. As far as etymological notes
are concerned this statement seems to require some modifica¬
tion. Omitting the explanations of proper names, we have
in the vulgate several cases where one etymology out of two
or more offered or quoted is distinctly preferred*: cortina, A.
6, 847; 8, 92; delubrum, A. 2, 225; 4, 56; fur, G. 8, 407;
harena, A. 1, 178; indigetes, A. 12, 79; G. 1, 498; latrones, A.
12, 7; lucerna, A. 1, 726; manes, A. 3,68; tus, G. 1,57; vesti-
bulum, A. 2, 469; 6, 278 and perhaps circenses, A. 8, 636; G.
3, 18. In an equal number of cases, however, no such pre¬
ference is manifested: amoenus, A. 6, 688; ancile, A. 8, 664;
annus, A. 1, 269; castra, A. 8, 519; clarigatio, A. 10,14; cuna-
* These etymologies aie quoted in the second part of this paper
8
CoLOEADo College Studies.
bula, B. 4, 23; foedus, A. 1, 62; palaestra, G. 2, 531; scopulus,
A. 1,45; senatores, A. 5, 758; sparus, A. 11, 682; urbs, A. 1,12.
As far as the etymologies in the additional notes are con¬
cerned, Thomas' statement seems to be strictly correct.
In this connection may be pointed out a few inconsist¬
encies which are found in the vulgate itself. For the words
cadaver, A. 6, 481; 8,264; cortina, A. 3, 92; 6,347.; delubrum,
A. 2, 225; 4, 56; fur, A. 9, 348; G. 3, 407, and Segesta, A. 1,
550; 5, 718 different etymologies are preferred in different
parts of the commentary. For Carthago, A. 1, 343; 1, 366;
4, 670; cedria, A. 6, 180; 7, 178, and formosus, A. 1, 359; 8,
453, we have, if not different etymologies, at least a more
general and a more exact explanation of each word in differ¬
ent places. For several words two etymologies are offered or
quoted in one place, only one in another: amoenus, A. 5,734;
6, 638; clarigatio, A. 9, 52; 10, 14; delubrum, A. 2, 225 ; 4,
56; fur, A. 9, 348; G. 3,407; scopulus, A. 1, 45; 1, 180; solium,
A. 1,506; 7,169. For scopulus the two derivations are offered
earlier in the commentary than the one which is apparently
preferred; for each of the other 6ve words the two optional
etymologies are not mentioned until after one of them has
been given.
IX. Sometimes etymologies are only implied: Acheron,
A. 6, 107 (quasi sine gaudio); dolones, A. 7, 664 (a fallendo
dicti); hydra, A. 6, 287 (ab aqua dicta); etc. Even when
they are more definitely stated it is sometimes difficult to
determine the exact meaning. For example, on the passage
'saepe volutabris pulsos silvestribus apros latratu turbabis
agens', G. 3, 411, we have the comment 'volutabra loca sunt,
in quibus se apri volvunt.' Is 'apri' part of the etymology,
and not due merely to the 'apros' of Vergil's line? Such
an explanation would not be too bad for Isidore, who has,
or. XVI 1, 5, 'volutabra appellata quod ibi apri volutentur',
and the notes on the following words suggest that such an
explanation was good enough for Servius: antarium, A. 11,156
(quasi ante aras); circenses, A. 8, 636; G. 3, 18 (vel a cir-
cuitu, vel . . . ab ensibus circa quos currebant); fatiscunt,
A. 1, 123 ('fatim' abundanter, hiscere aperiri); fortuitus.
Etymologies.
9
6, 179 (ab eundo et a fortuna); furcillae, G. 2, 389 (quibus
frumenta cillentur). A similar case is the explanation of
'legumen'. On G. 1,74, we read 'dicitur quod nianu legatur
nee sectionem requirat'; on G. 1, 199, '"manu legeret'; hinc
quidam volunt dictum legumen". The fact that Tegumina'
is represented in an old glossary by ysHpo-d seems to confirm
the suspicion that, if Servius himself did not derive the word
from legere -|- manus, he at least refers to such a derivation
in his note on G. 1, 199*. A third instance is the note on
'lugentes campi', A. 6, 441: "lugentes, quasi Tucis egentes'".
This is probably meant for an etymology, not merely the
explanation of a metaphor. Voss in his Etymologicon men¬
tions a derivation, 'ingeniosius quam verius', of 'lugere' from
i. e. ay-oria tenebrae'.
X. The difficult question of the sources of Servius' ety¬
mological notes must be reserved for a separate paper. At
present, however, two general statements may be made.
About thirty derivations are attributed to Varro, but he un¬
doubtedly was the ultimate authority for a good many more.
Verrius Flaccus is only once mentioned by name, but there
is much in these notes which must have come directly or
indirectly from the great work De Verborum Significatu.
This might have been inferred from the papers in which
Nettleship has pointed out some of the parallels between
Servius and Festus or Paulus. See his Ancient Commenta¬
tors to Vergil, prefixed to the fourth edition of Conington's
commentary, and the papers on Verrius Flaccus, Nonius
Marcellus and Thilo's Servius in his Lectures and Essays,
Oxford, 1885.
Many of the etymologies quoted in our commentary are
introduced by such general phrases as ' quidam . . .', 'alii . . .',
'fabula est . . .', etc., or by others which are almost as indefi¬
nite: 'ut lectum est in historia Poenorum' (Carthago, A. 1,
343); 'lectum tamen est in philologis' (Caieta, A. 7, 1);
' prudentiores tajpen dicunt' (Silvanus, A. 8, 601). On Aen.
* It maybe noted that the latest etymology offered for this 'word is also due to the
feeling that'legere' in itself is not sufficient to explain 'legumina'. Stowasser, Dunkle
Woerter, p, 29^ proposes legere -|- *um%na. " Umcn von uere, wie flumen von ftueret numen
von nuere, acumen- von acuere gebildet, bedeutet ersichtlich Huelle, Huelse."
10 Colorado College Studies.
7, 678, we have the following general statement: 'de civitati-
bus totius orbis multi quidem ex parte scripserunt, ad plenum
tamen Ptolomaeus graece, latine Plinius. de Italicis etiam
urbibus Hyginus plenissime scripsit, et Cato in originibus'.
Omitting the cases in which Vergil's own explanations of
words are discussed, we have etymologies distinctly referred
to the following authors:—
Aeschylus, pergama, A. 1, 95.
Alexarchus, Campania, A. 3, 334.
Marcus Antonius, Umbros, A. 12, 753.
An'sfoju'cMS, Campania, A. 3, 334.
Asper, solium, A. 7,169.
Ateius, Roma, A. 1, 273.
Carminius, amoenus, A. 5, 374.
Cassius, fana, G. 1, 10.
Cassius Hemina, Crustumerium, A. 7,631; magalia, A. 1,421.
Cato, Graviscae, A. 10,184; intempestae, A. 10,184; lulus, A.
1, 267; magalia, A. 1, 421; Praeneste, A. 7, 682; Sabini,
A.8, 638.
Cicero, foedus, A. 8, 641; seditio, A. 1,149; Tenedos, A. 2, 21.
Cincius, delubrum, A. 2, 225; fana, G. 1, 10.
Clinias, Roma, A. 1, 273.
Clodius Tuscus, mussare, A. 12, 667.
Conon, Sarrastras, A. 7, 738.
Donatus, latebat, A. 3, 636; Lenaeus, G. 2, 4; litus, A. 2, 557;
Parrhasio, A. 11, 31.
Ennius, Roma, A. 1, 273.
Eratosthenes, Myrmidones, A. 2, 7; Roma, A. 1, 273.
Gellius, Sabini, A. 8, 638.
HeracUdes, Roma, A. 1, 273.
Hyginus, Ardea, A. 7, 412; Caere, A. 8, 597; Casperuli, A.
8, 638; Hesperia, A. 1, 530; Sabini, A. 8, 638.
Livius, Campania, A. 3, 334; Carthago, A. 1, 343; 1, 366.
Lutatius, Baiae, A. 9, 707.
Masurius Sabinus, delubrum, A. 2, 225.
Naevius, Roma, A. 1, 273.
Nigidius, herba, G. 1, 120.
Ovidius, Ardea, A. 7, 412; names of months, G. 1, 43.
Etymologies.
. 11
Philochorus, Pelasgi, A. 8, 600.
Philostephanus, Trinacia, A. 1, 196.
Piso, Pilumnus, A. 10, 76.
Plmms, intempestae, A. 10,184; iunior, A. 6,304; lyciscae, B.
3, 18; sucinum, A. 8,402.
Postumius, Baiae, A. 9, 707.
Sallustius, magalia, A. 1, 421; senatores, A. 5, 758.
Saufeius, Aborigines, Cascei, Latiam, A. 1, 6.
Seneca, Abates, Philos, A. 6, 154.
Statins Tullianus, Camilla, A.ii, 543.
Thukydides, Italia, A. 8, 328.
Varro, amoenus, A. 5, 374; ara, 4, 219; arena, A. 1, 172;
Aventinus, A. 7, 657; Campania, A. 8, 884; candelabrum,
A. 2, 225; carceres, A. 5, 145; cernuli, A. 10, 894; curcu-
lio, G. 1, 186; delubrum, A. 2, 225; faunos, G. 1, 11;
focus, A. 11, 21; frenos, A. 8, 280; germanus, A. 5, 412;
harena, A. 1, 172; junior, A. 5, 409; 6, 304; Latium, A. 8,
322; latrones, A. 12, 7; Libya, A. 1, 22; Oenotria, A. 1, 532;
Palatinus, A. 8, 51; palla, A. 1, 648; proceres, A. 1, 740;
pronuba, A. 4, 166; senior, A. 5, 409; spams, A. 11, 682;
testudo, A. 1, 505; valvae, A. 1, 449; Varro, A. 11, 478;
vates, A. 8, 448; vestibulum, A. 6, 273.
Verrius Flaccus, juniperi, B. 7, 58.
Vitruvius, aditus, ostium, A. 6, 43.
XI. Sometimes we find Servius attributing to earlier
writers opinions which they apparently did not hold. Unless
it be supposed that Varro in his voluminous writings may
have preferred different etymologies for the same word in
different places, we must infer that he has been misrepre¬
sented at least two or three times.
amoenus.—Servius says, ad Aen. 6, 638, that Varro explained
amoena ' quasi amunia.'
Isidore, or. XIV 9, 33, makes Varro derive amoena
from amare.
Latium.—Serv.^ad Aen. 8, 322, Varro autem Latium dici
putat, quod latet Italia inter praecipitia Al-
pium et Apennini.
Varro, L.L. V 32, says Apulia and Latium are
named ' ab hominibus.'
«•
12
CoLOEADo College Studies.
vates.—Serv. ad Aen. 3, 413, Vates a vi mentis appellatos,
Varro auctor est.
Varro, L. L. VII 36, antiqui poetas Vates appella-
bant a versibus viendis.
ostium.—Serv. ad Aen. 6, 43, nam Vitruvius qui de archi-
tectonica scripsit, ostium dicit per quod ab
aliquo arcemur ingressu ab obstando dictum.
To use Thilo's words, falso Servius ostium, etc.' Vitruvio
tribuit.
II.—FALSE AND POPULAR ETYMOLOGIES.
The great value of Servius' etymological notes is apparent
to every reader of his commentary. There are, of course,
many derivations offered which are no longer accepted, but
many of the words which he attempts to explain still defy
certain analysis, and in some of the cases where he offers two
optional etymologies for the same word each of these has its
supporters at the present day. In the following pages an
attempt is made to collect all his etymologies which may be
confidently rejected. It is hardly necessary to disclaim any
pretence to completeness of treatment where completeness of
treatment is practically impossible. At the same time this
paper professes to contain all Servius' etymologies (excluding
proper names) which, according to the highest and.most re¬
cent authorities, are.no longer tenable. One word of expla¬
nation should be added. In cases where Servius offers two
optional etymologies of the same word both are regularly
quoted, often without comment. Large as the following list
is, it might have been much larger, had it included all the
unnecessary derivations of Latin words from Greek, cases, i. e.,
where the Latin word is at most cognate with the Greek, not
derived from it. In many cases Servius' statements as to the
exact relation between two cognate Latin words do not agree
with modern views. These too are regularly omitted, though
one or two extreme examples have been retained: fores, Aen.
1, 449 (quae foras aperiuntur); fundus, G. 2, 468 (rerum
omnium fundamentum).
As often as one of Servius' more remarkable etymologies
has been found in an earlier writer the passage is added below.
Etymologies.
13
but in no case is it definitely stated that he borrowed his note
from this source. It is somewhat surprising to find how few
of these appear in the extant works of his predecessors and
how many of them recur in Isidore, for whom no etymology
was too grotesque. It is hard to imagine that Servius is
himself responsible for all these ingenious explanations.
Whether Isidore drew directly upon Servius, as Thilo thinks,
or upon Servius' sources, as Nettleship maintains, he doubt¬
less preserves many derivations that were offered by Servius'
predecessors.
Such works as Palmer's Folk Etymology, Andresen's
Deutsche Volksetymologie, and Keller's Luteinische VolJcs-
etymologie deal chiefly with Folk Etymology in the narrower
sense of the term: where the form of a word is affected by
false derivation or mistaken analogy, or where the significa¬
tion is warped and perverted from a false relationship being
assumed. Even in this narrow sense of the term our com¬
mentary furnishes several examples of Folk Etymology.
Thus Servius, on Aen. 1,172, prefers the derivation 'arena ab
ariditate' to 'harena ab haerendo', where Varro left an option
and an optional spelling. The Sabine ' fasena' shows that the
initial'h' is etymologically correct*. On G. 1, 57, he says
that the old derivation of 'tus' («-<> too Oecou) led to the spell¬
ing 'thus'. Cases of perverted meaning due to mistaken
analogy are more numerous: see especially the notes on gur-
gulio, indigetes, latrones, orichalcum, and postumus, quoted
in the following pages. For the words indigetes and latrones
Servius himself distinctly mentions popular etymologies;
with these may be compared the comment on Aen 6, 392;
sane Alciden volunt quidam a-d akxi;? dictum, id est a vir-
tute: quod non procedit, quia a prima aetate hoc nomen
habuit abAlcaeo,patreAmphitryonis. et scimus agnomina ab
accidentibus dari.
Adoeea, Aen. 10, 677, ' Turnus adoro' id est juxta veteres,
qui adorare adloqui dicebant: nam ideo et adorea laus
bellica, quo(tomnes eum cum gratulatione adloquebantur,
qui in bellis fortiter fecit.
•Corssen, Vol. I p. 102,
u
CoLOBADO College Studies.
Aesculus, G. 2, 291, ab esu dicta.
Amellus, G. 4, 278, Mella fluvius Galliae est, juxta quern haec
herba plurima nascitur; unde et amella dicitur.
Servius' explanation seems to have been suggested by
Vergil's line, 'et curva legunt prope flumina Mellae'. See
Wharton, Etyma Latina,p. 4, "amellus starwort: Gaulish for
*ampellos ' loved by bees', fr. *ampis bee ( M spelt am, and p
disappearing in Celtic: see Stokes, B. B. 9,194), cf. OHG. impi
and gnat?"
Aminneum, G. 2,97, aminneum vinum dictum est quasi sine
minio, id est rubore; nam album est. et aliter: Amineos
Aristoteles in politiis hoc scrihit Thessalos fuisse, qui
suae^ reyionis vites in lialiam transtulerint, atque illis
inde nomen inpositum.
Amoenus, Aen. 6, 638, amoena autem quae solum amorem
praestant, vel ut supra (ad Aen. 5, 374, sc.) diximus, quasi
amunia, hoc est sine fructu, ut Varro et Carminius decent.
Paulus, p. 2, says 'amoena dicta sunt loca, quae ad se
amanda adliciant'. Isidore makes Verrius Flaccus derive«
' amoenus' from' munus', Varro from' amare'; orig. XIV 9,33:
'amoena loca dicta Varro ait eo quod solum amorem praestent
et ad amanda adliciant: Verrius Flaccus, quod sine munere
sint, nec quicquam in his ofl&cii, quasi amunia, id est sine
fructu etc'.
Ancile, Aen. 8, 664, ancile autem dicitur aut quasi undique
circumcisum, aut quasi dn^iysiXov, id est undique labrum
habens.
Annus, Aen. 1, 269, annus autem dictus quasi anus, id est
anulus, quod in se redeat, . . . vel d-o rou dvaveouaOat, id
est ab innovatione.
Antaeium, Aen. 11,156, sane hoc bellum 'antarium' vocari
solitum, quod sit ante urbem, quasi ante aras.
Apeicus, Aen. 6, 312, quasi drtp ^pixTj?, id est sine frigore ut
diximus supra (ad Aen. 5, 128, sc.)
cf. Paul. p. 2, apricum locum a sole apertum a Graeco
vocabulo <fpixr] appellatum, quasi dyptxij^, id est sine horrore,
videlicet frigoris, unde etiam putatur et Africa appellarii
Aea, Aen. 2, 515, dicitur a precibus, quas Graeci dpd? dicunt.
Etymologies.
15
Aen. 4,219, veteres aras ' asas' dicebantj postea inmu-
tata littera's^ in 'r' 'aras' dixerunt,sicut Valesios Valerias,
Fusios Furies: quod Varro rerum divinarum in libra quinto
plenius narrat
Aedea, Aen. 7, 412, sciendum tamen ardeam avem zar' avzi.
(ppaavj dictam, quod brevitate pennarum altius non volat.
G. 1, 364, ardea dicta quasi ardua.
Asylum, Aen. 2, 761, dictum 'asylum' quasi 'asyrum'. alii
'asylum' idea dictum, quad nullus inde ialleretur, id est
quad <TuXa(TOai, hoc est abripi, nullus inde paterat.
Aen. 8, 842, templum misericordiae, . . . unde nullus
posset abduci.
Atrium, Aen. 1,726, ibi et culina erat: unde et atrium dictum
est; atrum enim erat ex fumo. alii dicunt Atriam Etru-
riae civitatem fuisse, quae damas amplis vestibidis habe-
bat: quae cum Ramani imitarentur atria appellaverunt.
Augubium, Aen. 5,523, dictum quasi 'avigerium', id est quod
aves gerunt.
The same derivation is given ad Aen. 1, 393; 1,397; 1, 398,
2, 702; 8, 89; 6, 198.
cf. Paul. p. 2, augur ab avibus gerendoque dictus, quia
per eum avium gestus edicitur; sive ab avium garritu,
unde et augurium.
Bellum, Aen. 1,22, xazd avzi^paaiv, a nulla re bella.
cf. Charis. p. 276,15 K. antiphrasis . . . ut bellum dicitur,
quod minime sit bellum.
Donat. ars gram. p. 402, 4 K. ut bellum, hoc est minime
bellum.
Bidentes, Aen. 4, 57, 'bidentes' autem dictae sunt quasi
biennes, quia neque minores, neque maiores licebat hostias
dare, sunt etiam in ovibus duo eminentiores dentes inter
octo, qui non nisi circa bimatum apparent.
Aen. 6, 39, ' bidentes' autem ut diximus supra oves sunt
circa binlfetum, habentes duos dentes eminentiores.
Servius here combines two different derivations. The
derivation from 'annus' is mentioned by Aulus Gellius, who
16
CoLOEADO College Studies.
devotes a whole chapter to the word 'bidentes', and approved
by Nonius Marcellus.
of. Gell. XVI 6, 13, scriptum invenimus in commentariis
quibusdam ad jus pontificum pertinentibus, 'bidennes' primo
dictas, 'd' littera inmissa, quasi 'biennes', turn longo usu
loquendi corruptam vocem esse et ex ' bidennibus'' bidentes'
factum, quoniam id videbatur esse dictu facilius leniusque.
Non. Marc. Lib. 1, p. 53 M. bidentes qui existimant ob
eam cansam oves a Vergilio dictas quod duos dentes habeant,
pessime a vitio intellegunt et melius intellegi
potest, si hidennis quasi biennis dixeris auctoritate.
Beuma, Aen. 2, 472, dicta . . . quasi r^uap, id est bre.vis
dies.
G. 1, 211, hruma dicta a hreviorihus diebus.
Bueis, G. 1, 170, quasi l^od? oupa, quod sit in similitudinem
caudae bovis. alii . . . : huris enim id curvetur, ante
igni domatur, id est amburitur Vurro aitf totum
burim indici ab urbe.
Cadavee, Aen. 6,481, caduci ... a cadendo; unde et cada-
vera dicta.
Aen. 8, 264, cadaver est corpus nondum sepultum, dictum
cadaver quod careat honore sepulturae.
Aen. 11, 143, sane hacc corpora sive proici jubebantur
a cadendo, sive quod sepultura carebant'cadavera''
dicta.
Caesaeies, Aen. 1, 590; 8, 659, a caedendo dicta.
Calamisteum, Aen. 12, 100, acus maior, quae calefacta et
adhibita intorqueat capillos.
cf. Varr. L.L. V129, calamistrum, quod his calfactis in
cinere capillus ornatur.
Calculus, G. 2, 180, dictus, quod sine molestia sui brevitate
calcetur.
Caecee, Aen. 1, 54, dictus quasi arcer ab arcendo. G. 3,104,
ab arcendo dictus.
Aen. 5,145,' carceres' quasi' arceres' secundum Varronem.
cf. Varr. L.L. V 151, career a coercendo. V 153, carceres
dicti, quod coercentur equi.
Etymologies.
17
Varro at least attempted to account for the initial 'c'. To
Servius no such explanation would seem necessary.
See Caulae.
Casses, Cassus, Aen. 2, 85, cassum est quasi qunssum at nihil
continens; nam at vas quassum, quod humoram in sa nan
conlinat at est vacuum, unda at ratia casses, quod multum
in se vacui hahaant. Aen. 11, 104, 'cassis' vacuis: unde
et retia casses dicimus, et vestimenta araneorum casses
dicuntur.
cf. Non. p. 45, 9 M. cassum veteres inane posuerunt. Et
arbitrandum est eius verbi proprietatem magis ab
aranearum cassibus dictam, quod sint leves et nullius
ponderis, non, ut quibusdam videtur, quasi quassum.
Castok, G. 1, 58, castores autem a castrando dicti sunt.
O. Keller, Latainischa VolJcsatijmologia und Verwandtcs,
p. 285, derives castrara from castor, citing an ancient belief
(Cic.Ovid. Plin. Juven. Apulej.) concerning the beaver. 'Also
castrara aliquam heisst einen nach Biberart behandeln, seine
opx-^^ zerstoeren'.
Castka, Aen. 3, 519, dicta autem 'castra' quasi casta, vel
quod illic castraretur libido: nam nunquam his intererat
mulier.
Catus, Aen. 1, 428, id est ingeniosus «-<) rob xai^trOac.
cf. Donat. ad Ter. Andr. V 2, 14, catus: callidus, doctus,
ardens, r^apd to y.aUiv. unde Cato dictus. ingeniorum
. enim igneus vigor esse videtur.
Caulae, Aen. 9, 59, 'caulas' munimenta et saepta ovium.
est enim Graecum nomen 'c' detracto: nam Graeci dukd^
vocant animalium receptacula.
Servius evidently means to connect 'caulas' and duXd<;
etymologically, not merely to point out an interesting co¬
incidence in form. That the initial 'c' in the Latin word pre¬
sented no serious difficulty to him may be inferred from his
explanation of Qaulon, Aen. 8, 558, 'Aulon mons est Cala-
briae, etc.', and the comments on Cortina, Aen. 3, 92, and
Cakoee, Aen. 1, 54; 5,145.
18
Colorado College Studies.
Cedria, Aen. 6,180, cedria dicta est quasi xaiopj'^rii uypuv,
id est arboris umor ardentis.
Aen. 7, 178, 'e cedro'. unde et cedria.
Cernulus, Cernuus, Aen. 10, 894, cernuus equus dicitur, qui
cadit in faciem, quasi in earn partem cadens qua cernimus:
unde et pueri quos in ludis videmus ea parte, qua cernunt,
stantes, cernuli vocantur, ut etiam Varro in ludis tliea-
tralibus docet.
cf. Non. p. 21, 2 M., cernuus dicitur proprie inclinatus,
quasi quod terram cernat.
Chelydrits, Gi. 3, 415, 'chelydri' dicti quasi chersydri, qui et
in aquis et in terris morantur: nam yjpaov dicimus terram,
aquam vero udwp.
circenses, Aen. 8, 636, circenses dicti vel a circuitu, vel quod
ubi nunc metae sunt, olim gladii ponebantur, quos cir-
cumibant. dicti autem circenses ab ensibus, circa quos
currebant.
G. 3, 18, circenses dicti sunt, quia exhibebantur in cir¬
cuitu ensibus positis; licet alii a circumeundo dicant
circenses vocari.
circumvolat, Aen. 3, 233, ant circum praedam volat uncis
pedibus: ant intra volam amplectitur praedam: unde et
involare etc. See Yolando.
Clarigatio, a. 9, 52, a claritate vocis.
A. 10, 14, ant a clara voce qua utebatur pater patratus, aut
a xkTjpai, hoc est sorte.
Classis, a. 1, 39, dicta est a~d rihv y-dlwv, id est a lignis. So
a. 6, 1.
Cliens, a. 6, 609, si enim clientes quasi colentes sunt etc.
Cortina, A. 3, 92, dicitur autem cortina, vel quod Apollinis
tripos corio Pythonis tectus est, vel quod certa illinc
responsa funduntur, quasi certina, vel quod est verius,
quia cor illic vatis tenetur. alii coriinam quasi ortinam
tradunt, quod inde vox oriatur.
Etymologies.
19
A. 6, 347, Cortina dicta est aut quod cor teneat, aut quod
tripus saeptus erat corio serpentis, ut diximus supra:
aut certe secundum Graecam etymologiam ort zr/v xop-qv
zsLvet vj-oi Ttvdaast, id est quod extendi! puellam, ut
'maiorque videri'.
CuNABULA, Buc. 4, 23, lectuli in quibus infantes jacere con-
sueverunt: vel loca, in quibus nascuntur, quasi cynabula;
nam xueix est Graece niti.
Cuba, A. 1, 208; 4, 1, cura dicta ab eo quod cor urat.
cf. Varr. L.L. VI 46, cura quod cor urat.
Paul. p. 35, cura dicta est, quasi coreda, vel quia cor urat.
cueculio, G. 1, 186, Varro ait hoc nomen per antistoechon
dictum, quasi gurgulio, quoniam paene nihil est nisi guttur.
Defrutum, G. 2, 93, dictum, quod defraudatur et quasi
fraudem patitur.
Delubeum, a. 2, 225, delubrum dicitur quod uno tecto plura
complectitur numina, quia uno tecto diluitur, . . . alii, ut
Cincius, dicunt, delubrum esse locum ante templum, ubi
aqua currit, a diluendo (a deZwendo, Nettleship, Contrib.
p. 429.)
On A. 4, 56, a similar explanation is given with this addi¬
tion: aut certe simulacrum ligneum delubrum dicimus,
a libro, hoc est raso ligno factum, quod Graece ^oavov
dicitur.
Daniel's Servius on A. 2, 225, attributes this explanation
' a delibratione corticis' to Masurius Sabinus, and quotes an¬
other from Varro,divinarum libro fJCIX': aut in
quo loco dei dicatum sit simulacrum, ut {sicid) in quo figunt
candelam, candelabrum appellant, sic in quo deum ponunt,
delubrum dieant.
Nettleship, Lectures and Essays, p. 239, has compared two
parallel passages in Macrobius and Paulus, and suggests a
possible inference as to the source of Servius' information.
"Macrobius (3, 3) has one note, Paulus, p. 73, has another,
on this word. But the substance of both notes is combined
by Servius on Aen. 2, 225. Paulus says 'delubrum dicebant.
20
CoLOKADO College Studies.
fustem delibratum, hoc est decorticatum, quern venerabantur
pro deo'. Servius not only gives this explanation, but also
those quoted in Macrobius from Varro's Rerum Divinarum;
and much the same comment recurs, with an addition, in
Servius on Aen. 4, 56. The impression left is that both Ma¬
crobius and Servius were copying from an article inVerrius
Flaccus, of which only a short extract has survived in the
epitome of Paulus."
Deus, a. 12,139, nam quod graece Sio?, latine timor vocatur,
inde deus dictus est, quod omnis religio sit timoris.
cf. Paul. p. 50, deus dictus, quod ei nihil desit, . . . sive
a Graeco quod significat metum, eo quod homini-
bus metus sit.
Dira, a. 4, 453, dira enim deorum ira est.
A. 3, 235, Sabini et Umbri, quae nos mala, dira appellant,
cf. Paul. p. 49, dirus, del ira natus.
Non. Marc. p. 30, 14 M. dirum . . quasi deorum ira in-
missum.
Ebue, a. 1, 592, ebur a barro dictum, id est elephanto.
Extudeeat, a. 8, 665, studiose fecerat.
Fatiscunt, a. 1,123, fatiscuntabundanter aperiuntur; 'fatim'
enim abundanter dicimus, unde et adfatim, hiscere autem
aperiri.
Feea, a. 1, 215, feras dicimus aut quod omni corpore feruntur,
aut quod naturali utuntur libertate et pro desiderio suo
feruntur. So a. 2, 51.
Flagella, G. 2, 299, dicuntur summae arborum partes, ab eo
quod ventorum crebros sustinent flatus.
cf. Varr. R.R.I, 31, 3, neque ex se potest eiicere vitem,
quam vocant minorem flagellum, maiorem etiam unde
uvae nascuntur, palmam. prior, litera una mutata, de-
clinata a venti flatu, similiter flabellum ac flagellum.
Flageantia, a. 1, 436, quotiens incendium significatur, quod
flatu alitur, per '1' dicimus, quotiens odor, qui fracta
specie major est, per 'r' dicimus.
Etymologies.
21
Flamines, a. 8, 664; 10, 270, a 61o quo utebantur, flamines
dicti sunt quasi filamines.
cf. Varr. L.L. V 84, quod . . . caput cinctum habebant
filo, flamines dicti.
Paul. p. 62, Flamen Dialis dictus, quod fllo assidue vele-
tur; indeque appellatur flamen, quasi filamen.
Varro's explanation of this word is now generally rejected,
though De Vit says it is confirmed by an inscription
'ap. Gruter. 227, 6'.
Foedus, a. 1, 62, dictum vel a fetialibus, id est sacerdotibus
per quos flunt foedera, vel a porca foede, hoc est lapidibus
occisa, ut ipse 'et caesa jungebant foedera porca'.
The same explanation is given on Aen. 8, 641 and Aen. 12,
109. On Aen. 8, 641 Daniel's Servius adds: Cicero
foedera a fide putat dicta. On Aeii. 4, 242 we have
'fetiales afoedere\
cf. Paul. p. 59, foedus appellatum ab eo, quod in pacis-
cendo foede hostia necaretur. Virgilius: 'et caesa
jungebant foedera porca'. Vel quia in foedere inter-
ponatur fides.
Formica, A. 4, 402, sane 'formica' dicta est ab eo, quod ore
micas ferat.
Formosus, a. 1, 359, formosus a forma, ut a specie speciosus
etc.
A. 8,453, nam forvum est calidum: unde et formosos dici-
mus quibus calor sanguinis ex rubore pulchritudinem
creat.
cf. Paul. p. 59, Forma signiticat modo faciem cuiusque rei,
modo calidam, ut, quum exta, quae dantur, deforma
appellantur. Et Cato ait de quodam aedificio aestate
frigido, hieme formido.
Fores, A. 1, 449, fores proprie dicuntur quae foras aperiun-
tur, sicut apud veteres fuit.
Fortuitus, a. 6, 179, sane 'fortuitus' ab eundo est et a for-
tuna compositum.
Fragrantia, vide Flagrantia.
22
coloeado College Studies.
Feateia, a. 7, 286, Argos dipsion . . . , apud quos erat
magna societas inter eos qui uno puteo utebantur; unde
et fratrias dixerunt ano rod <ppiazo<s.
Feenos, a. 8, 230, nam et frendere significat dentibus' fran-'
gere . . . . et Varro frenos bine putat dictos.
Fundus, G. 2, 468, fundus dicitur ab eo, quod sit rerum om¬
nium fundamentum.
Funus, a. 1, 727, funera dicuntur, quod funes incensos mor-
tuis praeferebant. So on A. 6, 224, and a. 11, 143, where
another explanation is offered: alii a fungendo, quod eo
supremo in eo qui decessit, officio fungimur, vel quod hi
qui mortui sunt' vita fundi'' dicuntur.
of. Donat. ad Ter. Andr. 1, 1, 88: 'in funus': in ipsum
officium ant in pompam exsequiarum: quod a funali-
bus dictum est et uncis et cuneis candelabrorum, qhibus
delibuti funes cerei fomites infiguntur.
Fue, Fuetum, a. 2, 18, nam et furtum ideo dicitur, quod
magis per tenehras admittaiurj unde fares qui quasi per
furvum tempus, hoc est nigrum, aliqnid subripiunt. So
A. 9, 348.
G. 3, 407, fur autem a furvo dictus est, .... aut certe a
Graeco venit; nam fur fuip vocatur.
The derivation of 'fur' from 'furvum' is attributed to
Varro (in XIV rerum divinarum libro) by Gellius,
1, 18, 4; to Varro (rerum humanarum lib. XIV.) by
Nonius, p. 50, 9 M. Gellius himself explains 'fur' as
the Latin representative of f<i>p.
Fuecillae, G. 2, 389, nam 'cillere' est movere, unde et fur-
cillae dictae sunt, quibus frumenta cillentur.
Haeena, a. 1,172, quaeritur, habeat necne nomen hoc adspi-
rationem. Et Varro sic definit si ab ariditate dicitur non
habet, si ab haerendo, ut in fabricis videmus, habet.
melior tamen est superior etymologia.
Heeoas, B. 4, 35, quidam a terra dictos volunt, quod terra
spa dicta sit, unde initio nati creduntur homines, qui nomen
a matre traxerunt.
Etymologies.
23
Inclita, a. 6, 781, inclita Graecum est: nam gloriosum
dicunt.
cf. Paul. p. 39, clutum Graeci -/dorow dicunt. Unde accepta
praepositione fit inclitus.
Indigenae, a. 8, 814; 8, 328, id est inde geniti, auzoxOovs?.
iNDlGExfes, A. 12, 794, indigetes dii duplici ratione dicuntur:
vel secundum Lucretium, quod nullius rei egeant, qui ait
(11, 650 sc.) ' nihil indiga curae' . . . vel certe indigetes
sunt dii ex hominibus facti, et dicti indigetes quasi in diis
agentes. The fuller version adds: vel quod nos deorum
indigeamus . . . , alii patrios decs indigetes did debere
tradunt, alii ab invocatione indigetes dictos volunt, quod
'indigeto' estprecor et invoco.
G. 1, 498, indigetes proprie sunt dii ex hominibus facti,
quasi in diis agentes, abusive omnes generaliter, quasi
nullius rei egentes.
An incorrect form Indigens appears in a Pompeian in¬
scription, C. I. Ll. Vol. 1, p. 283, upon which the editor
remarks: ' Indigens pro indiges hoc solo loco reperitur,
ni fallor ex fabrili errato'.
Infeeiae, a. 10, 519; 11, 81, inferiae sunt sacra mortuorum,
quod inferis solvuntur.
Insertas, a. 3,152, aut clatratas; aut non seratas, ut sit quasi
insertas id est non clausas, et dictum quomodo . . . 'con-
postus' pro 'conpositus' . . . vel 'insertas fenestras'' quas
lumine sua luna inseruerat, ab inserendo, quod se per
rimas insereret.
Instaueata, a. 2, 15, 'instar' autem est ad similitudinem:
unde non restaurata sed instaurata dicuntur aedificia ad
antiquam similitudinem facta.
cf. Paul. p. 79, instaurari ab instar dictum, cum aliquid ad
pristinam similitudinem reficitur.
Macrob. Sat^I 11, 5, . . . isque instauratitius dictus est,
... a rediutegratione, ut Varroni placet, qui instaurare
ait esse instar novare.
24
CoLOKADO College Studies.
'Instaurare' may be cognate with 'instar', but is hardly
derived from it.
Involaee, a. 3, 233; G. 2, 88, involare dicimus intra volam
tenere. See Volando.
Ieeitum, a. 7, 421, in cassum id est in irritum: incassum
autem tractum est a cassibus, id est a retibus.
JuBAE, A. 4, 130, proprie 'jubar' lucifer dicitur, quod jubas
lucis effundit: est autem lucifer interdum lovis: nam et
antiqui 'juhar' quasi ^jtivar^ dicebant.
JuNiPEE, B. 7,53, Verrius Flaccus juniperum juvenem pirum
ait.
A AO I, G. 1, 63, nam et Graece jiopuli/«'/( dicuntur a lapidi-
bus.
The resemblance between people and xaa? stone is
implied in Hom. II. XXIV 611, Aaoo9 0£ AiOou<s ~oir^<Ji
hfjdviutv^ and Pindar explains the word from the legend
of Deucalion, O. 9, 66, -/.ziaaaaOav AiOivov yuvov Aa<n S'
ovuixaaOsv.
Latex, A. 1, 686, proprie aqua est ab eo quod intra terrae
venas lateat.
This derivation is accepted by Stowasser, Dunkle Woerter,
p. 5,' Richtig schon Isidor XIII 20, latex proprie liquor fontis,
quod in terra lateat'. It is surely better to regard latex as
the Latin representative of Arira?, with which it is sound for .
sound identical.
Lateones, a. 12, 7, est Graecum; nam karfisOeiv dicunt obse-
qui et servire mercede, unde latrones vocantur conducti
milites. Varro tamen dicit, hoc nomen posse habere
etiam Latinam etymologiam, ut latrones dicti sint quasi
laterones, quod circa latera regum sunt, quos nunc satel¬
lites vocant. latrones, ah laiendo.
The same three derivations are mentioned bv Varro, L.L.
VII 52.
cf. Paul. p. 85, Latrones antiqui eos dicebant, qui con¬
ducti militabant, ar,u ka~ps(ai. At nunc viarum
obsessores dicuntur, quod a latere adoriuntur, vel quod
latenter insidiantur.
Etymologies.
25
Legumen, G. 1, 74, dicitur quod manu legatur nec sectionem
requirat.
G. 1, 199, 'manu legeret'; hinc quidam volunt dictum
legumen.
Litus, a. 2, 557, quod autem Donatus dicit, 'litus' locum
esse ante aras, a litando dictum; vel quod lituo illud spa-
tium designatur, ratione caret: nam a litando 'li' brevis
est, et stare non potest versus.
A. 5, 163, 'litus' est omne quod aqua adluitur.
c£. Sueton. reliqu. p. 244, 5 Reiffers., litus, quidquid aqua
adluitur.
Lucus, A. 1, 22, lucus a non lucendo.
A. 1, 441, 'lucus' autem dicitur quod non luceat, non quod
sint ibi lumina causa religionis, ut quidam volunt.
cf. Quintil. 1, 6, 34 etiamne a contrariis aliqua sinemus
trahi, ut 'lucus', quia umbra opacus parum luceat, et
'ludus', quia sit longissime a lusu, etc.
Charis. p. 276, 15 K., antiphrasis . . . ut bellum . . . et
lucus, quod minime luceat.
Diomed. p. 462, 15 K., antiphrasis . . . ut bellum . . . et
lucus, quod minime luceat.
Lugentes (campi), A. 6, 441, quasi 'lucis egentes'.
Lustrum, A. 1, 607, aut 'lustrabant' inumbrabant, unde lustra
et ferarum cubilia et lupanaria per contrarium dicimus,
quia parum inlustrantur.
Maotabe, a. 4, 57, 'mactant' verbum sacrorum, zar eu(prjfxia/j.v'/
dictum, ut adolere, nam 'mactare' proprie est 'magis
augere'.
cf. Paul. p. 90, mactus magis auctus.
Sueton. reliqu. p. 275 E. mactatum autem quasi magis
auctum,
Non. p. 341,^16, mactare est magis augere.
Magmentum, a. 4, 57, quasi mains augmentum.
cf. Paul. p. 91, magmentatum*, magis augmentatum.
26
Colorado College Studies.
Malus, a. 5, 487, dictus est, vel quia habet instar mall in
summitate, vel quia quasi quibusdam malis ligneis cingi-
tur, quorum volubilitate vela facilius elevantur.
Manes, A. 1, 139, 'manum' enim antiqui bonum dicebant, . .
unde . . . per antiphrasin 'manes' inferi, quia non sint
boni.
On Aen. 3, 63, the explanation zard avrifpaar^ is repeated,
and another mentioned: alii manes a manando dictos
intellegunt: nam animabus plena sunt loca inter luna-
rem et terrenum circulum, unde et defluunt.
cf. Paul. p. 87, inferi di manes, ut subpliciter appellati
bono essent, et in carmine Saliari Cerus manus intel-
legitur creator bonus, cf. Test. Qu. VIII 38; Paul,
p. 131.
Paul. p. 149, Manes di ab auguribus vocabantur, quod eos
per omnia manare credebant, eosque deos superos
atque inferos dicebant.
Medius Fidius, a. 8, 275, 'communem deum' inter deos atque
homines: unde medius fidius dictus.
A. 4, 204, ut Sallustius 'quam medius fidius veram licet
mecum recognoscas': id est sis dictis medius: fidius
id est ^£09 ul6?, lovis filius, id est Hercules, medium
dixit testem.
cf. Paul. p. 131, Medius fidius conpositum videtur et sig-
nificare lovis filius, id est Hercules, quod lovem Graece
df'a et nos lovem, ac fidium pro filio, quod saepe antea
pro L littera D utebantur. Quidam existimant jusju-
randum esse per divi fidem: quidam per diurni temporis,
id est diei fidem.
Mustela, a. 2, 468; 9, 744, 'telum' dictum a longitudine:
unde et mustela dicitur, quasi mus longus.
Oppeteee, a. 1, 96, ore terram petere, id est mori.
Geichalcum, a. 12, 87, quod et splendorem auri et aeris duri-
tiam possideret.
cf. Paul. p. 7, aurichalcum vel orichalcum quidam putant
conpositum ex aere et auro, sive quod colorem habeat
Etymologies.
27
aureum. Orichalcum sane dicitur, quia in montuosis
locis invenitur. Mons etenim Graece opo<s appellatur.
OsciLLA, G. 2, 389, dicta sunt ab eo, quod in his cillerentur,
id est moverentur era: nam 'cillere' est movere. oscilla
autem dicia, sive quoniam capita et ora hostium in sum-
mis periicis figehantur, sive quia Jiunc lusum Osci dicun-
tur frequenter exercuisse et rem per Italiam sparsisse.
Ostium, A. 6,43, nam Vitruvius qui de architectonica scripsit,
ostium dicit per quod ab aliquo arcemur ingressu ab ob-
stando dictum, aditum ab adeundo, per quem ingredimur.
"Falso Servius'ostium . . . ingredimur'Vitruviotribuit";
Thilo.
Paganus, G. 2, 382, 'pagi' d^d rwv i. e. a fontibus, circa
quos villae consueverant condi: unde et pagani dicti sunt,
quasi ex uno fonte potantes.
cf. Paul. p. 121, pagani a pagis dicti. pagi dicti a fontibus
quod eadem aqua uterentur. Aquae enim lingua
Dorica naj-dt appellantur.
Palaestra, G. 2, 531, vel and tt,? ndXrj?, id est a luctatione,
vel and TOO ndXXstv, hoc est a motu urnae, nam ducti sorte
luctantur.
On Aen. 8, 138, the fuller version tells the story of the
Arcadian princess Palaestra, who disclosed to Mercury
the nature of her brothers' athletic contests, for which
reason all wrestling was known by her name.
Passum, G. 2, 93, dicitur a patiendo; nam decoquitur mustum
et inde fit passum.
cf. Non. p. 551, 22, Varro de vita populi Romani lib. I:
passam nominabant, si in vindemia uvam diutius
coctam legerent eamque passi essent in sole aduri.
Pausia, G. 2, 86, a paviendo dicta, id est tundendo; aliter
enim ex se oleum non facit.
Pecus, a. 1, 485, a pascendo.
Pernix, G. 3, 230, a pernitendo tractum est.
It seems much better, with Vanicek and Wharton, to de¬
rive pernix from perna, 'strong in the ham'. For term.
28 CoLOEADO College Studies.
cf. fel-ix. In the old etymology it is hard to see what
becomes of the 't" of nitor.
pollinctoees, A. 9, 485, qui mortuis os polline ohlinebani.
PoERiciAM, A. 5, 238, id est j)ori-o iaciam.
cf. Paul. p. 273, poriciam porro iaciam.
PosTUMUS, A. 6, 763, postumus est post humationem parentis
creatus.
cf. Varr. L.L. 9,60, postumus . . post patris mortem natus.
Pest. Qu. XII 8, p. 306, postumus cognominatur post
patris mortem natus.
Caesellius Vindex ap. Gell. II 16, 5, 'postuma proles' non
eum significat, qui patre mortuo, sed qui postremo loco
natus est sicuti Silvins, qui Aenea iam sene tardo
seroque partu est editus.
Preciae, G. 2,95, quasi praecoquae, quod ante alias coquantur.
Procul, a. 3, 13, 'procul' est quasi porro ab oculis.
A. 6, 10, procul enim et quod prae oculis est, et quod
porro ab oculis.
Pruna, a. 11, 788, a perurendo dicta est.
cf. Paul. p. 283, pruina dicta, quod fruges ac virgulta
perurat.
Recinus, a. 1, 282, recinus autem dicitur ab eo, quod post
tergum reicitur, quod vulgo maforte dicunt.
cf.Varr, L. L. V 132, ab reiciendo ricinium dictum.
Ruea, a. 1, 430, Graece apoupa dicuntur. aphaeresis ergo
sermonem fecit Latinum.
Sancire, a. 12, 200, 'Sancire' autem proprie est sanctum
aliquid, id est consecratum facere fuso sanguine hostiae:
et dictum sanctum, quasi sanguine consecratum.
ScoPULUS, A. 1,180, id est specula.
A. 1, 45, aut a speculando dictus, aut a tegimento navium
d~d Tdu <TX£7rd^ec'^.
ScuTRA, G. 1, 110, . . . scatebris bullitionibus. unde vulgo
vasa, ubi calida solet fieri scutrae appellantur.
Seouris, a. 1, 292, quasi semicuris.
Etymologies.
29
Segnis, A. 1,423; 5,374, id est sine igni. [Cf. the explanation
of Oatus quoted above.]
This etymology is doubtful at best, and, unless Servius
means only ' se igni', it is phonetically impossible. Sto-
wasser, Dunlde Woerter, p. 10, quotes Isid. or. X 19
{segnis aus se igne) in support of his explanation of
'prospere'.
Senatores, a. 5, 758, senatores autem alii a senecta aetate,
alii a sinendo dictos accipiunl.
A. 1, 426, legitur apud quosdam, Brutum eos qui se in
eiciendis regibus iuvissent legisse in consilium, eumque
ordinem senatum appellatum, quod una sensissent,
.... alii senatum a senectutehominum,\quibi allecti
erant, dictum volunt, qui apud Graecos yspouijia appel-
latur.
Sepultus, a. 3, 41, 'sepulto' modo mortuo vel jacenti signifi-
cat . . ; nam sepultus est quasi sine pulsu. non enim
hunc sepultum possumus dicere, cum sepultura non sit in
hoc rite facta, sed fortuita sit obrutus terra,
cf. Donat. ad Ter. Andr. 1, 1, 101, Sepulcrum xar avTiippa-
aiv, ut diximus, quod sine re pulcra sit: an quod ibi sine
pulsu sint, id est, mortui? sepulcrum enim a
sepeliendo dictum.
sinistrum, A. 2, 693, a sinendo dictum.
cf. Fest. Qu. XV 13, p. 502, Sinistrae aves sinistrumque
est fsinistimum auspicium, id quod sinat fieri.
Solium, A. 1, 506, dictum quasi solidum.
A. 7, 169, secundum aliquos a soliditate dictum, secundum
Asprum per antistoechon, quasi sodium a sedendo.
Spaeus, a. 11, 682, Varro ait sparum telum missile, a piscibus
ducta similitudine, qui spari vocantur. alii 'sparus' a
spargendo dici putant.
cf. Paul. p. 489, spara parvissimi generis iacula a spar¬
gendo dicta.
Stella, A. 5, 42, poetice dixit: nam si stella a stando dictae
sunt, non fugantur; semper enim fixae sunt praeter pla-
netas.
30 Colorado College Studies.
SuDUM, A. 8, 529, est quasi sub udum, serenum post pluvias,
ut ver sudum. alii '■sudum' semiudum volunt did, cum
2Jer nubes ad nos perveniat solis ictus non integer.
Telum, a. 2, 468, telum enim dicitur secundum Graecam
etymologiam a-b rod rr^XbOev, quidquid longe iaci potest.
So on Aen. 8, 249; 9, 507; 9, 744.
of. Fest. Qu. XVI 8, p. 556, Tela proprie did videntur ea,
quae missilia sunt, ex Graeco videlicet translate eorum
nomine, quoniam illi TTjkbOev missa dicunt quae nos
enniusf.
Tebritorium, a. 5, 755, dictum quasi terriborium tritum
bubus et aratro.
cf. Varr. L. L. V 21, Terra dicta ab eo, ut Aelius scribit,
quod teritur Territorium quod maxime teri-
tur.
Torus, Aen. 5, 388, 'torus' a tortis dictus est berbis. So on
Aen. 2, 2; 1, 708.
cf.'Non. 11, 11, Tororum et toralium designator est Varro
de vita pop. Kom. lib. I: quod fronde lecticae strue-
bantur, ex eo herba torta torum appellatum.
[cf., however, Varr. L.L. V 167 Torus a torvo, quod is in
promptu.]
Tumultus, a. 2, 486; 8, 1, dictus quasi timer multus.
cf. Cic. Phil. VIII 1, 8, quid est enim aliud tumultus nisi
perturbatio tanta, ut maior timer oriatur? unde etiam
nomen ductuni est tumultus.
Tus, G. 1, 57, sane 'tus' mode sine aspiratione dicimus; nam
antiqui'thus'dicebant flTTo too Osioo-. quod displicuit; tura
enim a tundendo dicta esse voluerunt, a glebis tunsis, cum
quibus dicitur fluens de arboribus coalescere.
cf. Charis. p. 75, 13 K., tus a tundendo sine adspiratione
dicitur, quamvis lulius Modestus a-b too Oueiv tractum
dicat.
Urbs, a. 1, 12, urbs dicta ab orbe, quod antiquae civitatesin
orbem fiebant; vel ab urvo, parte aratri, quo muri desig-
nabantur.
Etymologies.
31
cf. Varr. L.L. V 143, quare et oppida, quae prius erant
circumducta aratro, ab orbe et urvo urbes.
Uei, G. 2, 374, dicti 'uri' aitb r&v 6piu>v, id est a montibus.
vates, a. 3, 443, vates a vi mentis appellatos, Varro auctor
est.
cf. Varr. L.L. VII 36, antiqui poetas Vates appellabanta
versibus viendis.
Venenum, a. 1, 688, venenum dictum quod per venas eat.
a. 4, 2, quia per venas amor currit . . . sicut venenum.
Vekbenae, a. 12, 120, qnidam sane veris proximi herbas
verbenas dicunt.
Bug. 8, 65, a viriditate verbenae appellantur.
Vestibulum, a. 2, 469, vel quod ianuam vestiat, . . . vel
quoniam Vestae consecratum est.
A. 6, 273, vestibulum ut Varro dicit, etymologiae non
habet proprietatem, sed fit pro captu ingenii: nam
vestibulum, ut supra diximus, dictum ab eo, quod
ianuam vestiat. alii dicunt a Vesta dictum per inmi-
nutionem: nam Vestae limen est consecratum. alii
dicunt ab eo, quod nullus illic stet; in limine enim
solus est transitus: quomodo vesanus dicitur non sanus,
sic vestibulum quasi non stabulum.
Sulpicius Apollinaris, quoted with approval by Gellius
XVI 5, derives vestibulum from ve stabulum, but
gives a different force to the prefix. Nonius, p. 53,
prefers this explanation to that from Vesta.
victima, Aen. I, 334, victimae . . . sacrificia quae post vic-
toriam fiunt.
cf. Fest. Qu. XVI 25, p.*562, victimam Aelius Stilo ait
esse vitulum ob eius vigorem. alii aut quae vincta ad-
ducatur ad altare aut quae ob hostis victos immoletur.
vipeea, G. 3, 4I6»quae vi parit.
viega, A. 4, 242, dicta quod vi regat.
viego, Buc. 3, 30; 6, 47, a viridiore aetate.
32
CoLOKADo College Studies.
ViEOSA, G. 1, 58, dicta ab eo, quod est virus; alii fortia ac-
cipiunt a viribus.
vitula, Bug. 8, 30, a viridiore aetata dicta.
A. 1, 533. Oraeci hoves hahw?, nos vitulos dicimus.
VoLANDO, A. 6, 198, alii 'volando' ambulando dicunt: vela
enim dicitur media pars pedis sive manus.
cf. Non. Marc. p. 32, 31 M., involare est inruere, insilire,
aut a volatu,aut a vela, id est media manu, dictum.
PROPER NAMES.
No part of a language allows freer play to popular etymol¬
ogizing than its proper names, for no part of a language is
more difficult to explain. Servius himself appreciated in
some measure the difficulty of this part of his task. On Aen.
7, 678, he says that it is not surprising that many conflicting
explanations are offered for ancient Italian names, 'nam an-
tiquitas ipsa creavit errorem'. On Aen. 1, 273, Daniel's Ser¬
vius quotes a great many explanations of the name 'Eoma'.
These are prefaced by the remark: sed deorigine et conditore
urhis diversa a diversis traduntur. Accordingly, many such
words as Argiletum (Aen. 8, 345); Aventinus (Aen. 7, 657);
Palatinus (Aen. 8, 51) are provided with several etymologies
each.
No attempt is here made to pronounce upon all Servius'
explanations of proper names, but the following brief list will
show most of the phases of popular etymologizing which are
to be expected in an ancient commentary upon words of this
class. "False etymologies are of themselves the fruitful
causes of myths" (Sayce, Science of Language, Vol. II, p.
259). "The eponymous heroes from whom tribes and nations
have been supposed to derive their names owe their existence
to the same popular etymologizing etc." Ilbid.p. 247.'\ In
our commentary myths are recounted ad nauseam, and the
hero eponymous appears on almost every page. Sometimes
these ancient tales are rejected as fabulous, and rational ex¬
planations inserted to replace them. Thus Servius explains
I
Etymologies.
33
away the stories of the origin of the Myrmidones (Aen. 2, 7),
the strange birth of Orion (Aen. 1, 535), and of Minotaurus
(Aen. 6, 14), the she-wolf that suckled Romulus and Remus
(Aen. 1, 273), etc.
In any language foreign words are especially liable to cor¬
ruption. cf. Paul. p. 13, ' Alumento pro Laumedonte a vete-
ribus Romanis necdum adsuetis Graecae linguae dictum est.
sic Melo pro Nilo, Catamitus pro Ganymede, Alphius pro
Alpheo dicebatur'. See also Paul. p. 6 (v. Alcedo); p. 31
(v. Catamitum); p. 89 (v. Melo). If a language could repre¬
sent ravu,arjd7j? by Catamitus, -e/zdAij by Stimula, it is not sur¬
prising to find its ancient commentators offering numerous
popular etymologies for its proper names—and especially for
names of foreign origin—as they manfully tried to assign
meanings to these unintelligible words by deriving them from
words of similar sound. Many of these explanations are
obviously suggested by well known peculiarities of climate,
product, or character.
Finally may be mentioned one or two examples of a ' per¬
verse ingenuity', which discovers a certain appropriateness
in the names of some of the actors in the Aeneid. Not con¬
tent with the statement on Aen. 12, 391, "lapix, aptum nomen
medico; nam iaaOai Graeci dicunt curare," Servius has two
curious comments on Achates' name, on Aen. 1, 174 and
1, 312. For these see the first word in the following list.
Achates, Aen. 1, 312, diximus quaeri, cur Achates Aeneae sit
comes. Varia quidem dicuntur, melius tamen hoc fingi-
tur, ut tractum nomen sit a Graeca etymologia. enim
dicitur sollicitudo, quae regum semper est comes.
Aen. 1, 174, adlusit ad nomen. nam achates lapidis spe¬
cies est: bene ergo ipsum dicit ignem excussisse. unde
etiam Achatem eius comitem dixit.
Acheeon, Aen. 6, 107, quasi sine gaudio.
Acidalia, Aen. 720, Acidalia Venus dicitur vel quia inicit
curas, quas Graeci axtda? dicunt, vel certe a fonte Acidalio
qui est in Orchomeno
34
Colorado College Studies.
Africa, Aen. 6, 812, . . . apricis, quasi arep <fpix-^<s, id est sine
frigore; unde non nulli et Africam dictam volunt.
Aen. 5,128, 'apricum' autem quasi avet^ sine frigore:
inde et Africa, quod est calidior.
of. Paul. p. 2, apricum locum a sole apertum a Graeco
vocabulo fpixTq appellatum, quasi a^puiji, id est sine
horrore, videlicet frigoris, unde etiam putatur et Africa
appellari.
Amazon, Aen. 1, 490, dictae vel quod simul vivant sine viris,
quasi Spa Z&aai, vel quod unam mammam exustam habe-
ant, quasi avsu pat^ou. i
Aen. 11, 651, nam hoc est Amazon, quasi aveu paZod, sine
mamma.
Arcturus, Aen. 1, 744; G. 1, 67, quasi apxrou ovpd.
Charon, Aen. 6, 299, xazd avzifpaaiv, quasi dyaipwv.
The resemblance between the words yaipwv and Xdpwv was
sufficient for a Greek pun (Ar. Ran. 184, yaXp^ <u Xdpiuv),
but Servius' rule for agreement of quantity should
have prevented him from connecting them etymologi-
cally.
CuMAE, Aen. 3, 441; 6, 2, vel drtb t&v xupdzwv, vel a gravidae
mulieris augurio, quae Graece eyxuas dicitur.
Cybele, Aen. 3, 111, 'Cybeli' id est montis Phrygiae, a quo
et Cybele dicta est. alii a Cybelo sacerdote,
.... alii and TOO xu^tarav Trjv xefaXi/v, id est a capitis rota-
tione.
Etrdria, Aen. 10, 164, ah Etrusco principe.
Aen. 11,598, Etruria dicta est, quod eius fines tendebantur
usque ad ripam Tiberis, quasi ^zspoupia-, nam irspov est
alterum, o/>"? finis vocatur.
Hecate, Aen. 4, 511, quidam Hecaten dictam esse tradunt,
quod eadem et Diana sit et Proserpina, and rwv ixazipwv:
vel quod Apollinis soror sit, qui est ixarrjiSolos.
Hyades, Aen. 1, 744, hyades stellae sunt in fronte tauri, quae
quotiens nascuntur pluvias creant: unde et Graece Oddes
dictae sunt and zou uecv, Latine suculae a suco . . . alii
Etymologies.
35
dicTint hyadas dictas vel ab T littera vel drcd too id est
sue, in cuius formatae sunt faciem. The same three ex-
planations are given on G. 1, 188. Daniel's Servius adds
on Aen. 1, 744, quidam hyadas ah Hyante fratre etc.
of. Cic. N. D. II48, § 111; Tullius Tiro ap. Gell. XIII 9,4;
Plin. N. H. XVIII 26, § 247.
Ieis, Aen. 5, 606; 9, 2; Iris dicta quasi epi<;.
Ianus, Aen. 7, 610, quidam lanum Eanum dicunt ah eundo.
cf. Cic. N. D. II 27, 67, lanum . . . , quod ab eundo
nomen est ductum.
lovEM, Aen. 1, 47, lovem autem a iuvando dixerunt. See
luppitee.
luno, Aen. 1, 4, cum a iuvandp dicta sit luno etc.
cf. Varr. L.L. Y 67, dicta quod una cum love iuvat, luno.
Cic. N. D. II 26, 66, Sed lunonem a iuvando credo nomi-
natam.
luPPiTEE, Aen. 4, 688, 'luppiter' iuvans pater.
cf. Cic. N. D. II 25, 64, sed ipse luppiter id est 'iuvans
paterquern conversis casibus appellamus a iuvando
lovem.
Gell. V 12, 4, lovem Latini veteres a iuvando appellavere,
eundemque alio vocabulo iuncto 'patrem' dixerunt.
Nam quod est elisis aut inmutatis quibusdam litteris
' lupiter', id plenum atque integrum est' lovispater'.
Kponos, Aen. 8,104, quasi Xpovo?.
cf. Cic. N. D. II 25, 64, Kpovo? enim dicitur, qui est idem
id est spatium temporis.
Lenaeus, Aen. 4, 207; G. 2, 4, d-nd rod Itjvod. In each passage
Servius rejects Donatus' explanation, mentioning him by
name in the second: nam quod Donatus dicit ab eo, quod
mentem deleniat, non procedit; nec enim potest Graecum
nomen Latinam etymologiam recipere.
Libee, Aen. 4, 688, a libertate.
G. 1, 166, ab eo, quod liberet, dictus.
36
Colorado College Studies.
G. 1, 7, quamvis Sahini Cererem Pandam appellent,
Liberum Loehasium, didum autem, quia graece koifiij
diciiur res divina.
Libya, Aen. 1, 22, dicta autem Libya vel quod inde libs flat,
hoc est africus, vel, ut Varro ait, quasi AIIIITIA, id est
egens pluviae.
Lupeboal, Aen. 8, 343, sub monte Palatino est quaedam
spelunca, in qua de capro luebatur, id est sacrificabatur:
unde et lupercal non nulli dictum putant. alii quod illic
lupa Remum et Romulum nutrierit: alii, quod et Ver-
gilius, . . . ergo ideo et Evander deo gentis suae sacravit
locum et nominavit lupercal, quod praesidio ipsius nu-
minis lupi a pecudibus arcerentur.
Maenala, G. 1, 17, mons Arcadiae, dictus 'i~o twv iJ.rpMv^ id
est ab ovibus, quibus plenus est.
Meecueids, Aen. 4, 638, quod mercibus praeest.
Aen. 8,138, alii Mercurium quasi Alediciirrium a Latinis
didum volunt, quod inter caelum et inferos semper
intercurrat. hie etiam mercimonii deus est.
cf. Arnob. Ill 32, Mercurius etiam quasi quidam Medi-
currius dictus est.
«
For a curious explanation of this word see Wilmanns,
De Terent.Varr. Libris, pj. 175: 'Mium et commir-
cium per I antiquis relinquamus, apud quos aeque et
Mircurius per I dicebatur, quod mirandarum esset
rerum inventor, ut Varro dicit'.
ntlus, Aen. 9, 30; G. 4, 291, dictus quasi viav iUov, hoc est
novum limum trahfens.
Pan, Buc. 2, 31, deus rusticus, in naturae similitudinem for-
matus, unde et Pan dictus est, id est .omne etc.
cf. Hom. Hymn. XVIII 47, Ilava 3i jxtv xakisaxov, vTC (ppiva
Ttaaw ersptl's.
Poeninae, Aen. 10,13, loca quae rupit (Hannibal sc.) Poeni-
nae Alpes vocantur. quamvis legatur a Poenina dea etc.
Peaeneste, Aen. 7, 678, locus dictus a-o rSxv T.pivwv, id est ab
ilicibus.
Aen. 7, 682, Cato dicit quia is locus montibus praestet.
Etymologies.
37
PeOMETHEUS, Buc. 6, 42, ai:d t^9 T:poii-qOeta<s.
Sabaei, G. 1, 57, aTo TOO ai^saOai, quod apud eos tus nascitur,
quo decs placamus.
SucuLAE, Aen. 1, 744, Graece vdSets dictae sunt aizb too oscv,
Latine suculae a suco.
Daniel's Servius on Aen. 1, 744, and G. 1, 138, gives the
other explanation, ' a suibus
of. Gellius, XIII 9, 15, quod ab illis 'oddss\ a nobis primo
'syades', deinde suculae appellantur.
Tusci, Aen. 2, 781; 8, 479; 10, 164, a frequentia sacrificii
dicti, hoc est dnd too Oosiv.
cf. Paul. p. 537, Tusci a Tusco rege, filio Herculis, sunt
dicti, vel a sacrificando studiose, ex Graeco velut
Ooaxoot.
Tartarus, Aen. 6, 577, and Tapaxrji, aut, quod est melius,
and TOO TapTapiZsiv id est a tremore frigoris.
Vesta, Aen. 1, 292, and ttj? iaTia? . . ., vel quod variis vestita
sit rebus.
Aen. 2, 296, . . . quod vi sua stet.
cf. Ovid. Fast. VI 299, stat vi terra sua: vi stando Vesta
-vocatur.
ZETE, Aen. 1, 388, luppiter, quo constant omnia, Zso^s vocatur
and id est vita.
cf. Plat. Cratyl. 396 B, Zfjva . . . 8C Sv Zi,v del ndai TO!? ?ai(7£v
ondp^ec.
NOTES ON JEFFERSON'S DRAFT OF THE
ORDINANCE OF 1784.
By W. M. HALL.
THE "SEVENTEEN STATES" PLAN.
McMaster speaks of the plan for seventeen States as if it
were wholly thrown aside by Jefferson's committee. "One plan
was to divide the ceded and purchased lands into seventeen
States. Eight of these were to lie between the banks of the
Mississippi and a north and south line through the falls of
the Ohio. Eight more were to be marked out between this
line and a second one parallel to it, and passing through the
western bank of the mouth of the Great Kanawha. What
remained was to form the seventeenth State. But few sup¬
porters were found for the measure, and a committee, over
which Jefferson presided, was ordered to place before Congress
a new scheme of division. Chase and Howe assisted him, and
the three devised a plan whereby the prairie lands were to be
parted out among ten new States." *
These "ten new States" lay north of the Ohio; except, as
will presently be seen, parts of two of them. Nevertheless it
seems clear that the Ordinance was meant to provide govern¬
ment for all the Western country that the States might cede,
down to the southern line of the United States at 31°. The
surrender of some State claims south of the Ohio was expected,
and North Carolina did pass a short-lived act of cession a few
weeks after. Jefferson was laboring to persuade the Southern
States to cede all their territory west of the Great Kanawha
meridian. The Ordinance reported by his committee begins
by saying that "the territory ceded or to be ceded by indi-
* Volume I., page 165. But since the following comments were read before the Society,
Volume III. of Mr. McMaster's History has been published, containing (at page 101) a
seemingly full recognition of the substantial identity of the two plans.
NOTES ON JEEFEESON'S DRAFT.
89
vidual States to the United States .... shall be formed
into additional States, bounded .... as nearly as such
cessions will admit .... northwardly and southwardly
by parallels of latitude, so that each State shall comprehend,
from south to north, two degrees of latitude, beginning to
count from the completion of thirty-one degrees from the
equator; but any territory northwardly of the forty-seventh
degree shall make part of the State next below." (Then are
described the north-to-south lines, viz., the Mississippi and the
meridians of the Ohio falls and the mouth of the Great
Kanawha.) If we were to understand "the territory ceded
or to be ceded by individual States" as an unguarded phrase
meaning merely such territory north of the Ohio (a strange
oversight when cessions south of the river were under dis¬
cussion), the expected cessions being those of Massachusetts
and Connecticut only, it would be hard to account for the irre¬
levant mention of the thirty-first degree line, which is about
six degrees south of the southernmost point of Illinois; and it
would be equally hard to see why, in the detailed statement
of boundaries further on, a State ("Pelisipia") was made of
two small blocks of land between the thirty-ninth degree line
and the Ohio east and west of Cincinnati, which should
naturally have been attached to the adjoining square State,
Saratoga, as the points of the two Michigan iDeninsulas had
been attached to other States.
The difficulties vanish when we regard the reported Ordi¬
nance as dealing with the whole lYestern country, from 31"
up, the first paragraph laying an outline of States by drawing
east-and-west lines every two degrees up to 45", and a meri¬
dian line through the falls of the Ohio (Louisville)* dividing
each of these strips into two States, with another meridian
line through the mouth of the Kanawha cutting off what is
now Eastern Ohio into a State by itself. Here we have two
rows of eight States each, and an odd State further east; the
• Apparently the n^ridian of Louisville was believed to enter Lake Michigan near
the southern end. For the Illinois river, t. e., its Kankakee branch, is mentioned in the
later paragraph of details as one of the rivers whose sources lie in Metropotamia, east of
that meridian. The same is suggested, though less clearly, by the description of Michigania
as wholly west of the lake, without remark upon this as a de\iation from the meridian
system.
40
Colorado College Studies.
"seventeen States" still undiminished. This is the general
scheme; and a later paragraph applies it in detail for the
region north of the Ohio, which was already ceded except the
two strips claimed by Massachusetts and Connecticut; the
northeast corner State of the general scheme, consisting chiefly
of lake surface, is extinguished and the points of the Michigan
peninsulas are given to the contiguous States. Two of the ten
States here bounded and named lie partly in Kentucky, Peli-
sipia being thus no mere .remnant north of the Ohio. Six
States of the general scheme are not here named nor particu¬
larly bounded; doubtless because they lie in the still unceded
region south of the Ohio, and the eastern boundaries of the
expected cessions are not certainly known. The "ten States"
plan is thus a mere definition of part of the "seventeen States"
plan, and Jefferson's draft represents both.
ridicule of the draft.
The proposed list of State names (rejected by Congress)
was a cause of great hilarity in its day, and the pleasure is
shared by some recent historians. It can scarcely be that
their amusement comes from any other feature of the plan,
for the comparatively small size of the States was due to an
express requirement in Virginia's deed of cession,* and the
attempt to lay down State lines was not untimely, for the
lines drawn by the more famous Ordinance of 1787 are, with
little change, those that separate Ohio, Indiana, and Illinois.
We must look to the names alone for the supposed absurdity,
and there a mere glance seems to prove it—Sjdvania, Michi-
gania, Chersonesus, Assenisipia, Metropotamia, Illinoia, Sara¬
toga, Washington, Polypotamia, Pelisipia.
At a second glance the list is less formidable. Michigania,
Illinoia, Washington, are names that have since won the pre¬
ference of States; and Sylvania is a manifest improvement
upon Pennsylvania. Saratoga is a blameless commemorative
name. The absurdity is reduced to the other five. As to
those, no one will pretend that better names, for three at least,
might not have been found easily. But there is room for
*The larger States of the Ordinance of 1787 were made in view of an expected modifica¬
tion of Virginia's deed, which duly followed.
Notes on Jefpeeson's Draft.
41
question whether they are worse, or much worse, than the
names that States have deliberately taken to themselves or
received from their European sponsors. Two come legiti¬
mately enough from the Indian names, Assenisipi and Peli-
sipi, of the Kock and Ohio rivers; and it is not easy to frame a
canon of euphony that will reject these and accept Mississippi,
Massachusetts, Connecticut and Minnesota. The Grecian
or would-be-Grecian aspect of Metropotamia, Polypotamia
and Chersonesus need not have offended the sensibilities of
a Congress that was accustomed to hold sessions in Annapolis
or Philadelphia. Indeed, in the short list of our cities of a
hundred thousand inhabitants appear three names, either
Greek or of a lamentable Greek admixture—Philadelphia,
Minneapolis and Indianapolis, besides other curiosities like
Cincinnati, Chicago, Omaha, Milwaukee, Allegheny, Provi¬
dence and Buffalo. And if the comparison be kept strictly to
names of States, the error of Jefferson's list towards Greek is
perhaps offset by its superiority in other points; it has no name
out of a story-book like California; none so commonplace as
New Hampshire, New Jersey and New York; none so angular
as Wisconsin, Arkansas, Massachusetts and Connecticut; none
so mongrel as Pennsylvania; none so cumbrous as Rhode-
Island-and-Providence-Plantations.
It may accordingly be urged that the amusement over
Jefferson's names comes not from any unusual oddity in them,
but from the fact that others have been taken instead. If
Assenisipia and Polypotamia had been adopted, they would
doubtless pass unnoticed now, like Mississippi and Indian¬
apolis.
SOME NOTES ON BLAYDES' NL'BES.
By AUGUSTUS T. MUEEAY.
It is is not the purpose of this paper to give a detailed
review of Blaydes' work. His editorial methods are well
known and his thorough acquaintance with comic diction is
deservedly praised. It is in this respect that his editions are
most useful, giving as they do a wealth of illustration invalu¬
able to every student of Aristophanes. Of course this must
be offset by his contempt of manuscript tradition, shown in
this very play by the introduction or suggestion of many
hundred variations from the vulgata.
Added to this is the thoroughly unscientific character of
the commentary in which views are maintained and retracted,
and utterly divergent ones substituted, apparently according
to the whim of the moment. This very volume might have
been reduced in bulk surely one third, if a thorough revision
had been carried oiit. Many passages are now absurdly in¬
consistent (see e. g. text, critical note and addenda, vs. 811),
and while in Blaydes' eyes it may be a small sin to adopt one
reading in the text and another in the commentary, yet to all
believers in painstaking accuracy this fault is a grievous one.
The same carelessness shows itself in matters of fact; e. g.
on vs. 151 we are told that Dindorf and Teuffel give the read¬
ing (/'uyeiarj, whereas both have the earlier Attic form (I'uxeiar/.
Again the addendum on vs. 1365 is said to be drawn from
"Teuff. II" while it really comes from Kock. (The same
error in addendum to vs. 1192.) In the commentary on vs. 225
[Plat.] Axiochus 872 B. is referred to as Aeschin. Axioch.
22. But surely the identification is ungrounded; cf. Teuff.
Uebersicht p. 85. After reading in the text asiSsr^, (vs. 298)
it is absurd to read in the critical note " Dedi doidw'^," although
it is true we find half a dozen lines further down " Vel potius
des'^ejy."
Some Notes on Blaydes' Nubes.
43
Such examples might easily be multiplied, and the editor
himself is not unaware of their existence; see introd. p.
xxxvii. It is, however, foreign to my purpose to criticise
these details. I wish rather to discuss certain of his readings.
It will be interesting to start with his own exposition of
his views in regard to Aristophanic criticism. Regretting
the fact that for the Nubes the Ravennas and Venetus have
not as yet been as thoroughly collated as we could wish, he ,
continues: " Fatendum tamen est non valde magnum auxilium
vel ab iis expectandum esse, quum mendorum quibus nostri
textus maculatur non pauca inveterata sint et ejusmodi ut
sine conjecturae ope nunquam tolli queant." This is the
ground for the adoption or suggestion of many hundred vari¬
ations from the vulgata, as if he were correcting a schoolboy's
exercise! What shall we say to the array of " hariolationes"
in the critical note to vs. 995? or to the samples of his
critical acumen given in the introd. p. xxxv f.?
I propose to discuss certain passages in detail.
Vs. 24.—Strepsiades is cursing himseli for having bought the
"iTZTtov ■A<i--aTiav and exclaims—
snV i^sxoTZTjV T:pvT£/j()V ruv iiipftakiibv kiffu).
There is not the slightest ground for rejecting the reading
of the MSS. and Scholia. Close parallels are given by Tenffel,
especially Plant. Men. 152 (158) oculum ecfodito mihi si
ullum verbnm faxo.
Kuster however suggested i^sxoTzrj and has been followed
by Hermann, Meineke and Dindorf, the last of whom gravely
remarks, "Equo si elisus fuisset oculus, non emendus fuisset
Strepsiadi." Blaydes not only adopts this reading but sug¬
gests further "^bv irepov o<p'9, "quum non p.ov6<p^takp.oi sint
equi." This is triviality itself. Of course the dual and plu¬
ral often occur, but there are a number of cases, some cited
by Blaydes himself, where the singular is found.
See e. g. Aves. 1611 ff.—
(Irav dpvuj^Ti? zbv yJipa/.a xai rbv A(a,
6 xbpaz 7:apsk3cbv TuuTicopxobvTo? Xd9pa
izpoffTzrb/j.sxo'! ixx6<l'ei zbv 6<p9a?.p.bx ftl'xwx.
44
Colorado College Studies.
Ach. 91 ff.—A «! vT)v clyoiiTei lyAoiuv 9sudaprriiSav
Tov i3a<Ti).i(u<s oipf^alpow. Die. ixx6(/i£te ye
xopaS Ttard^a? tov ye (Tuv tou t:pe(7i3iu)^.
Dem. 18. 67, of Philip.—tov d <pi3akp.bv ixxexoppj'xov,
Lucian Tox. 24.—tov 6<ffkakp.bv ixxexopidvrj.
Men as well as horses are not iKfM'xpfkakpjn.
Vs. 151.—xaza 4'oxst(Trj Ttepii^uffav llepaixai.
So Dind. and Teufif. The MSS. differ only in giving the
later form (I'oyeiffrj. Kock and Meineke give the easy reading
<f'Uj(ivTn? (Herwerden i^'uyiyro?) of which Teuff. well says; "Die
Aenderung (I'uyivro? liegt zu nahe als dass sie wahrscheinlich
waere." Why in the world Aristophanes should have pre¬
ferred to say "when the flea became cold," rather than "when
the wax cooled," is a question that has not been answered and
the reading is suspicious. Certain, however, it is that 4>vyeiai^
did not come from the easy Nothing is gained by
Blaydes' adoption of (toI? r.oaC) and he will find no
followers.
Kaehler's 4'^yj'^'^oii (proleptic) is worth noting.
It is characteristic that while Blaydes gives in his
text, we read in the commentary "■ 4''jxsi<jrj sc. tj Sed
corrigendum videtur 4''^yJ'-''^'"s ("^"5 zij/jhD)."
Vs. 225 f.—Soc. dep()i3aTw xa\ T:epi<ppovu) tov TjXtov.
Streps. s~e:T aTzb zappou tou? i9eou? urep^poveT?
dk.y oux diio t9/? yrj?, elrzep;
Blaydes changes uizeptppovei? to au ~ept<ppoveT?, (an exceed¬
ingly slight change and a very clever one), on the ground that
b-ep<fpove'i? should govern the genitive and because the sense
demands T:epi<ppovei?.
We would at first glance expect the same verb, but the
reading is supported by all the MSS. and the scholiast, and the
verb on closer inspection seems purposely varied. Socrates
means, "I am speculating about the sun," (for this sense of
■nepKppove'iv cf. 741, 1503), but the words can be taken as, "1
am making no account of Helios," and it is in this sense that
Strepsiades takes them. This meaning of ■Kepi^poveXv does
Some Notes on Blaydes' Nubes. 45
occur, althouf^h Thuc. 1, 25 seems to be the only classic in¬
stance. Others can, however, be adduced from later writers;
see Kriiger's note on Thucyd. loc. cit.
Strepsiades therefore uses the common word for contem-
ning, oTtspippovetv,
As to the acc. with this last vb. cf. Thucyd. 6. 68.2, 3. 89.5,
Aesch. Pers. 825, Eur. Fr. 545 N^
For Strepsiades' taking words in a different sense from
the speaker, see 236, although there it is from inability to
understand them. Perhaps 248 is to be explained in the
same way. (Teuff.^)
In my opinion the passage is perfectly sound, and Blaydes'
suggestion, while very ingenious, is to be discarded.
Vss. 369 ff.—Soc. has denied the existence of Zeus. Strepsi¬
ades then asks, amazed, akkd Ti<; Sei; to which' Socrates
replies:
auzai SijTiou. ■ jieydkoi^ 81 <t iyib auzo 8i8dzw.
<pipe, ydp ~U)Ttt)z^ clveu Ne(pekwv uoyz' ijSrj ze'^edtrac;
xaizoc aifkpta'i uecy ahzoy^ zauza? 8' d-()8rjp.elv.
In vs. 369 Eeisig reads zouzo from inferior MSS., so
Blaydes, a reading which is easier but unnecessary. In 371
Blaydes takes exception to aozov and casts it out, accepting
ooffij? before oetv, which is also found in some MSS. That is,
however, unquestionably a gloss to explain al8p{a? and can
readily be paralleled, while the use of the genitive alone is
very common.
Blaydes' grounds for ejecting auzov are that it itself is ap¬
parently a gloss, (uoyza is used absolutely in 370), and that
there is nothing for it to refer to, "nisi illud additum hie
statuas majoris emphasis causa propter sequens raura?."
But that is exactly the case, and the reference is clear from
what precedes. There is no difficulty whatever and the auzoy
adds force.
Vs. 493.—8i8oixd^\ w r^pea^uza^ p.rj zzk-qywv 8isi.
Blaydes with Dindorf, but against the MSS., reads 8irj,
noting that the subj. is necessary. In this he seems clearly
wrong, despite Elmsley's authority. See Goodwin G. M. T.^
46
CoLOEADO College Studies.
§ 369 and Kriiger 54. 8. 12. Some of Blaydes' passages are
not to the point and in others the verbs are indicative.
Vs. 575. to <Ti)<f(I>raT()i i^sarai, deupo tov vouv ~p(>ai)rste.
So the MSS. and TeufiP. (Kaehler). Kock and Mein. follow
Bentley in reading Tcpoa'^sTs. Dindorf and Blaydes -pdaa'/sTs^
in order to avoid the tribrach in the fourth dipody.
Blaydes brings forward a number of passages to show
that the verb is not exclusively in the present tense. These
are worth examining; what he does not tell us is, that in every
case cited from Aristoph. the best MSS. have the present.
Of the sixteen passages he cites, Nub. 685, Eq. 1014, Pax
174, Thesm. 25, 881, Plut. 118, Pherecrat. II 840, Cratin. II
189, Antiph. Ill 29, Alex. Ill 508, may be dismissed off hand
as giving simply npuas'/e rdv vouv, generally in trimeter, and
without a variant.
In Nub. 1122 (Trochaic tetram.), Eq. 508 (anapaestic
tetram.), Vesp. 1015 (anapaestic tetram.), Av. 688 (anapaes¬
tic tetram.) and in the present passage, the MSS. agree in
giving(In Vesp.1015 /'^have'r/}o<T;^£T£,butIiy show
-poaix"e). Bentley changed throughout to -pda'/ere, and is
followed by most editors. Dindorf prefers -puaayszs through¬
out, while Bergk, Teufif. and Kaehler retain the present.
Blaydes is hopelessly inconsistent both in text and commen¬
tary, vacillating from one reading to another. In his latest
note, however, (addenda vs. 575 Nub.),he inclines to Dindorf's
view. In view of this, Kaehler's note, (Anhang p. 197), is to
the point: "Die Herausgeber haben vielfach in r.pdaysTs
npoaaysre geaendert, ohne Grund, wie es sich nach dieser
auffaelligen Uebereinstimmung zeigt, nur einem metrischem
Gesichtspunkte zu liebe."
There remain two instances of -pdaiays (one is plural),
Eupolis II 488^K. 87, and II 575=K. 886, (the first is not in
Kaehler or in Jacobi's index s. v. voO?), and finally Blaydes
omits the only instance of the aorist in comedy, Pherecrates
II 288=79 K. T.poaysTs Tov vouv. In SO short a fragment met¬
rical grounds cannot be conclusive, but this aorist may be so
accounted for.
Some Notes on Blaydes' Nubes. 47
Therefore, while it must be admitted that the aorist im¬
proves the metre in tetrameters, Blaydes' rule, (Aves. 688
addenda), "Scribendum ut in libris r.ptxriysre,'''' or Nub. 575
not. crit.), "Quare non nimis festinanter corrigendum
wjoo(r(7/eTe" is a safe one. He has not, however, followed it
himself.
Vs. 592. elra (piiimrr-qTS toutou tw rov auyiva—.
Few will follow Blaydes here in accepting from Lys. 680
the verb iyxafhtpixo^etv and rewriting the present passage thus:
iy/,a^'}app6<!rire rou-ou '9 ro ^I'lXov tuv auyiva^
although the phrase <fip.ouv zbv ahyha -w ^uXw does not occur
elsewhere.
<pip()hv from its very unusualness must be the true reading,
and the question is only whether we should read z(p ?bXw or
\ TW SuXtp.
In view of Eq. 394 iv $uXw Srjaa?, Eq. 705 TW ^bXw drj(TW^
and similar passages, it would seem that we must follow
Elmsley in inserting the preposition in that phrase even where
the MSS. do not have it, e. g. Eq. 367 <ni>v «■£ dijtrw tw SbXw. Eq.
1049 is interesting; there the MSS., (R. excepted, which has
^xiX,£uae) have,
TOOTOVt
drjfTat G TZt^xirtGopiyYia
The preposition is found in the quotation in the Etym.
Mag. p. 346, 18. Evidently the scribes mistook IxlUo iv for
ixiXsusv, and then the v was lost before the consonant.
From this analogy may be expected in our phrase; so
Sauppe, Dind., Kock, Mein. and Elmsley on Ach. 343.
I am inclined, however, with Teuff. and Kaehler, to regard
the dative as causal.
Vss. 743 ff.—
ey' dTpip.a xav dizopfji ti twv vorjpATwv^
d~sXde x-aza zrjv yvwprjv rtdXiv
xivrjaov avdi^ auzb xai Zoywdpirrov.
The variants*are dzpipa?, many MSS., and ndXac for TzdXiv
R.S.V. R. has also xaza for xaza.
The passage can hardly be sound as it stands, although it
is kept by Bergk, Dind., Mein., Teuff. Bergk suggested xai
48
CoLOEADO College Studies.
xara for xara^ but that does uot satisfy, for the phrase xivsiv rd
v6rj!J.a xard TY/v yi/w/xr/v is strange enough. Blaydes quotes the
suggestion with approval.
Meineke proposes rfj yxd'/j.rj or a5 au, (for auro), of which
the latter is certainly not to be accepted, as there is no stress
upon the pronoun. The former, t&d. already been
suggested by Keiske and is, I think rightly, accepted by Kock
and Kaehler. vuvj/ia tj" yxm/xyj xtveXv is not tautological. Blaydes
objects, "quum xivuv ty^'x yvmixY^v bene dicatur, non item xi>£r»
voYjrxa" after which it is strange to read in the commentary
"ty/v yvmixYfj xAvY^aov—nisi corrigendum rj yvmiiri—xivY/trov^-mente
id (to voYj/xa) agita"!
Blaydes further adopts y^v d" for xdv to avoid a difficulty
which is only apparent, as d-£)M refers to a different activity
and does not contradict the e/ drpi/xa.
Again in vs. 745 he reads auzu re, assigning to xvxy/ito-x and
Zuywf^piauv different objects. The sense is good but the change
is needless, and the re solitarium should not needlessly be
foisted into trimeters. Not satisfied with this, he offers the
choice between auro re, xai rdya^ xai Ytdhv, xwjrixa, aurixa re,
elra de.
Accepting Reiske's tj yvmpYj^ I think the passage is sound
without further change.
Vs. 823.—xai (Tin <ppd(TU) re Yzpdyix 8 txadiiiv dvijp etrei.
So R.V. and others while many MSB. give 8 au and omit
rc. For once Blaydes gives us no critical note, although he
follows Dindorf in rejecting the reading of R.V. Why the
other reading should be preferred it is hard to say, and to
give it to one's readers without at least noting the alternative
is inexcusable in an edition which claims to be critical.
Vs. 1046.-8 Tt77 xdxiijrvv Icrri xai deikuv izoieX rdv avdpa.
So the MSB. save that R. has deikd-arov ■, which, however,
is easily explained by the preceding xdxiarov (Dind). All edi¬
tors, Blaydes excepted, accept the reading and there is no
serious objection to it. Blaydes comments: "Versus valde
frigidus et nostro indignus. Displicet inter alia ruv dudpa.^'
He reads, therefore, dnij x-dxiarov abrd xdi deihizarov dvdpa TioieX,
Some Notes on Blaydes' Nubes. 49
as Eeiske had suggested, but as if to show his independence,
suggests alternatives which are characteristic enough to be
quoted in full. " Vel onrj xaxuv ijAyxiv re , Vel zaxdv
TO Xifiia xai ilstAuv ztv wjdpa :zoc£c, (vel SscAoraroy cl'xdpa -oje?), Vel
urtij xaxo'x r't? tooj tzovou? xai Seikov avdpa rofsi, Vel o~trj iia?.axov
h (cf. 1048. 1049.), \ el ^ttij xaxdv tov ■/p(I)ij.evo'x, (vel
htup.svuv^ xai SsiXov clvSpa Trojei, Vel or:;; yuvatxuxlrf rs xa't xaxov
(tJefAo!/) . . . ." And yet another; but one's patience gives
out. Who can call this criticism ?
Vs. 1415. —xX.douai Tzalde? Traripa 3' ou xkaxi'j doxst?.
Blaydes brackets this line as spurious, wrongly as it
seems. Metrical difficulty there is none. The additions in
various MSS. are attempts to complete the tetrameter, but
the poet purposely inserts the trimeter to make the parody
more apparent; and in view of the metrical scolium there can
be no doubt that the trimeter is intended.
More reasonable is the objection to ^ozer? in this sense
(hence Oobet oh ^prjvat, Herwerden doxsi? -Kpoayjxsiv), but in my
opinion the close resemblance to Euripides' verse excuses it,
and any addition makes the resemblance less close.
To cast out the verse is* surely wrong, but it is in line
with Blaydes' treatment of another parodic passage, vs. 30,
where on the traditional ti k'jia ps, he remarks "An xpiax;
(debitum)?" a suggestion which robs the passage of half its
force.
ON EURIP. IPH. TAUR. Vss, 351 ff.
By AUGUSTUS X. MUKRAY.
y.a\ TiiuT «//' ^tV.a;
ol duiTTU^et? yaft TaXaiv suTuyetrripm^
auTin xaxwi -/)d^avT£<s ou ifiiovooaiv eu"
So the MSS. save for Dindorf's certain correction of
fj(rfHi[xrjv for x^X'^dtxryx.
Seidler changed the xaxw? of vs. 853 to zaAd>s, and para¬
phrases thus: "Infelices, qui ipsi aliquando felices fuerunt,
felicioribus se non bene volunt." He is followed by Dindorf,
Nauck, Paley, and Jerram, (of the editions I have at hand).
Schoene and Flagg keep the zaztS?, which Schoene explains
as causal,—"weil sie unglilcklich geworden sind." That
seems, however, impossible. Nor will many follow Wecklein
in reading roXat SuirTu.xsirripotg and zazd)?, and interpreting, "Die
Unglucklichen meinen es nicht gut mit den noch Ungluck-
licheren wenn sie selber Leid erfahren haben."
The objection to Seidler's rendering is, to my mind, two¬
fold. In the first place, we need a -ori or Tzddai-, so that
Dindorf's nd?.at xa/.w<s is an improvement; or, better, Rauch-
enstein's au-<n 7n>r et> npd^av-sr, and secondly, in what respect
are Orestes and Pylades more fortunate than Iphigenia?
They had been, it is true, but now that they are brought face
to face with death, their lot is not an enviable one. If in
Iphigenia's eyes death was preferable to her state, it was an
alternative she could at any time have chosen.
The reference must*be to those who have been more fortu¬
nate but who have fallen into adversity, (as have Orestes
and Pylades). The envy and bitterness caused by their for¬
mer good fortune steel the hearts of the dLxrruxsXi against
them.
On Eurip. Iph. Taur. Vss. 351 If. 51
Hence KirchofF, (followed by England), would read aunn?
xazto? Tzpd^aiTtv. But why the abroi referring to the
has its proper force, but a'^ror? is more than super¬
fluous with Tirt(nv ebTU}(e(Trif>o'.?.
I feel certain, therefore, that we are nearer the truth in
reading;
(>l SufTTfj^et'^ yap roliTtv ebrw/^efTTipoi'^
dray xaxw^ Tzpd^axTtv od tppoyoTxriv ey.
The abzoi may have been added by some scribe who mis¬
took the subject of Ttpdztuatv and wished to make the reference
clearer. When once abzoi had crowded out ozav the subj.
would naturally be changed to the participle.
DRAPER'S BAROGRAPH.
By FLORIAN CAJOHI.
The description of Draper's Barograph in the Scientific
American Supplement, No. 209, 1880, contains the following
passage: "Heat has a slight effect on them (the springs),
causing them to lengthen about iV of an inch for 90 degrees
Fahr.; .... Other wise this instrument gives the correction
for temjjerature (or reduction to 32 degrees) from the fact
that it iveighs the mercury instead of measuring its length,
tvhich is affected by heat."''' This statement appears to be
considered correct, for we are told that in the use of Draper's
Barograph no corrections are made for variations in tempera¬
ture of the mercury.
It is the object of this paper to point out that the state¬
ment quoted in italics is erroneous. The instrument in
question consists of a tube 36 inches long, the upper portion
being of larger diameter than the lower. The tube is held
firmly in a fixed position and filled with mercury. Its lower
end dips into a movable cistern which is suspended on two
spiral springs. When the atmospheric pressure diminishes,
part of the mercury flows from the tube intodhe cistern; this
becoming heavier, stretches the steel springs, causing the ink
pencil fastened to them to mark downwards. If the pressure
increases, the opposite movement takes place.
The error referred to can be established by the following
reductio ad absurdum: All the mercury in the instrument
is supported by the movable cistern except that which is in
the fixed tube above the surface of the mercury in the cistern.
Now, if we suppose the atmospheric pressure to be constant,
but the temperature of the mercury to vary (the temperature
of the springs remaining the same), then, if the quoted state¬
ment is correct, the cistern should neither rise nor fall, else
Draper's Barograph.
53
the instrument would wrongly indicate a change of atmos¬
pheric pressure. If the cistern does not move, it supports
the same weight as it did before the change of temperature.
Hence the mercury in the fixed barometric tube extending
from the surface of the mercury in the cistern upwards, must
have the same weight as it had before. This weight is in part
balanced by the atmospheric pressure and in part rests upon
the fixed tube at the place near its upper end where it be¬
comes suddenly broader. The atmospheric pressure, being
assumed constant, supports the same weight of mercury as
before; hence the fixed tube likewise supports the same
weight as before. But the tube supports always a definite
and constant percentage of the entire mass of mercury in the
broad part. Hence mercury cannot pass in either direction
between the broad and narrow parts of the tube, for such a
passage would alter the total amount of mercury in the broad
end. and also the portion upheld by the tube. If these de¬
ductions are true, then mercury in the narrow part of the
tube cannot expand when the temperature rises, since it is
impossible for the mercury to pass either into the wider part
of the tube above or into the cistern below. The statement
quoted at the beginning must therefore be wrong, for it
leads to an absurdity. A change of temperature in the mer¬
cury, the pressure of the atmosphere remaining constant,
does affect the reading of the instrument.
What actually takes place during a rise of temperature,
at constant pressure, may be briefly indicated as follows: The
mercury in the narrow tube begins to expand down wards as well
as upwards, causing a small amount to escape into the cistern.
The increase in the mass of the liquid in the cistern, together
with the lengthening of the steel springs, due to the rise in
temperature, will thereupon cause the cistern to fall. By the
several readjustments the mercury column supported by the
atmospheric pressure is lengthened to such an extent as to
make the weight qf the new column supported by the atmos¬
pheric pressure equal to the weight of the old one, which
was shorter on account of the greater density of the mercury
at a lower temperature. There is now less mercury than be-
54
Colorado College Studies.
fore in the wide part of the fixed tube and more of it in the
cistern. Hence, a rise in temperature of the mercury tends to
make the instrument read too low. With the aid of somewhat
elaborate equations the writer has calculated that for a rise
of 45 degrees Fahr. in the mercury (at constant atmospheric
pressure) the cistern will fall about .174 inches. According
to the figures in the S. A. S. No. 209, the springs will stretch
about .03 inches, making an aggregate depression of .204
inches for 45 degrees, and thereby causing the atmospheric
pressure to appear .048 inches lower than it actually is. An
experiment with the barograph at Colorado College caused
the cistern to fall .211 inches for a rise of 45 degrees Fahr.
The experimental and the calculated figures are in fairly close
agreement.
The conclusion then is that Draper's Barograph reads
too low for temperatures above the standard temperature and
too high for temperatures below the standard. It is not ■uf-
ficient to make corrections for the stretching of the springs,
for the errors arising from variations of temperature in the
mercury are over five times greater.
It has been the practice to compare the barograph, from
time to time, with a standard barometer, but the results are
not satisfactory. Suppose comparisons are made at 12 m. It
is easy to adjust the barograph so that it will indicate very
nearly the same atmospheric pressure as does the barometer
at noon, except on days when the temperature varies widely
from the average noon temperature. But what about the
barograph readings in the morning before sunrise, when the
temperature is much lower? Will the barograph then not in¬
dicate a pressure altogether too high? Suppose the tempera¬
ture in the early morning be 10 degrees less in the barograph
case than it is at noon, then if the barograph reads correctly
at noon, it will read nearly .02 of an inch too high in the
morning. This is a serious error. If tables be constructed
for temperature corrections in Draper's Barograph, it will
not be difficult to use the barograph independently of a
standard barometer and to secure results of much greater
accuracy than those obtained at present.
THE CONDITIONAL IN GERMAN.
By SYLVESTER PRIMER.
Two opinions obtain in regard to the origin of the two
so-called conditional modes in German, ich wuerde loben,
ich wuerde gelobt haben, the one advanced by Jacob Grimm
in his Deutsche Grammatik, 4,183 fif., the other first proposed
by Vernalaken, Deutsche Syntax, II, 283 ff., which soon found
favor with others. However, these two opinions are not so
opposed that they cannot be considered complements to each
other.
In O.H.G. the Latin Imperfect, Perfect and Pluperfect
Subjunctives were expressed by the Imperfect Subjunctive
(wari, etc.); the Latin Perfect Subjunctive was also expressed
by the Present Subjunctive. The M.H.G. added a Perfect
form (Compound of the Present), but the Imperfect was not
limited to the expression of the Latin Imperfect Indicative or
Subjunctive, for it still retained its old Perfect force. Thus
the Imperfect finally expressed the Latin Imperfect proper
and the Aorist Perfect, while the Compound of the Present
(bin gewesen) expressed absolute past time. The result was
a loss in the differentiation of the Imperfect and Aorist, but a
gain in that of the Aorist and Perfect. Right here the Ro¬
mance Languages excel the German and Latin, for they have
three tenses (j'6tais, je fus, j'ai etc.). If, then, for the
Indicative the differentiation between the Aorist and Perfect
was more important and essential than that of the Imperfect
and Perfect, the exact opposite was true with regard to the
Subjunctive, where there is little to narrate, but a clearer dif¬
ferentiation of incomplete and complete past time is essential.
Grimm therefore argues that the Imperfect Subjunctive could
not suffice for the Imperfect tense, since there were un¬
avoidable encroachments of the simple Preterite (Aorist) upon
the Present on account of the wearing away of the form of
56
CoLOKADo College Studies.
the Present Subjunctive. The result of this was a new peri¬
phrasis, by means of which all modern German Languages
have enlarged their Subjunctive by one more tense than the
Indicative. This is called the Conditional, in imitation of the
Romance Grammarians. The auxiliaries forming the future
also serve in the German Languages for this Periphrastic
Conditional, and its signification is just the same as in the
Romance Languages. It cannot, according to Grimm, have
arisen earlier than the Periphrastic Future.
This conditional idea, says Grimm further, was at first ex¬
pressed by soUen, and still is in dialects where sollen is'used
for the future (cf. Netherl. zaiide, Engl, should and would,
Swed. skulle, Dan. skulde). Mid.H.G. also uses solde and
icolde in the same sense. A Mid.H.G. wuerde with the Infini¬
tive is just as unheard of in the poets of the 13th cent, as the
present tense-form loirde as periphrastic future. In the llth
and 15th cent, isolated examples are found: louerdent schacizen
{aestimarent), Ls. 1,15, and in the 16th cent, wuerde sagen
is as common in the language as iverde sagen. The Subjunc¬
tive forms sollte and wollte, which had become less clear be¬
cause they lacked the umlaut, is easily recognizable in imierde;
it must therefore be considered a Subjunctive tense and not
Indicative.
Furthermore this periphrastic form coincides with the sim¬
ple Preterite Subjunctive in its signification. The Mid.H.G.
disiu zuht gienge billicher ueber mich,lw. 1678, nor im genaese
niemen, Ben. 380, corresponds to a Mod.H.G. wuerde ergehen,
wuerde genesen, though the simple tense may still be used,
as in Mid.H.G. might have been said, solde gan. Both tenses,
the simple and periphrastic, thus compete according to cir¬
cumstances, as in the Indicative gieng and ist gegangen. But
gienge has a broader field and in many-cases cannot be re¬
placed by wuerde gehen, while gienge can almost always re¬
place wuerde gehen. Wuerde gehen, wuerde lieben never
have optative force, and are thus differentiated from the passive
periphrastic form of the Preterite Subjunctive, which is not
to be placed on the same footing with it and was present
much earlier in the language. Wuerde uf getan (aperire-
The Conditional in German. 57
tur), Iw. 12B4, and similar expressions are found everywhere
in the 13lh cent, and earlier, never nnicrde tif tiion (aperiret),
and the orij^in of the perixjhrasis of the two is different.
Wucrde aufgcthan fills quite the role of the Preterite Sub¬
junctive and has optative force. A passive conditional ac¬
quires further periphrasis by inierde auf<jethan ircrden, and
this liarallels the active inicrdo (uifihun. From this we see
that wuerde aiiffliiin cannot be a mere Subjunctive form of
trnrd (iitfthiin, since these Indicative perijjhrastic forms have
not been maintained in the language (Grimm, loc. cit. 185f.).
The second opinion is thus set forth by Vernalaken (loc.
cit. II, 283f.). It is well known that the future er ivird fra-
fien had an imxjerfect form icard or ivurde firigen. Wiird, in
the beginning joined to the preterite participle, then to the
infinitive, umlauted and umerde was used consequently as
conditional along with sollte and icollte. All four absolute
forms of the Subjunctive, kaeme, tvaere gekommen, wuerde
{sollte) kommen, tcuerde (sollte) getcommen sein, are used as
conditionals. Since the subjunctive form is less readily recog¬
nized in sollte, tvollte than in wuerde, the subjunctive form of
the futurum and futurum exactum has become more frequent
in late years. However, it must not be overlooked that all
four absolute subjunctive forms can be used both independ¬
ently ( that is, in independent clauses), and dependently (that
is, in dependent clauses). Moreover it belongs to the nature
of the conditional sentence to employ the absolute future
Subjunctive, viz., the conditional present and past, both in-
dicatively and subjunctively,as in French, where the forms are
just the same, e. g., in the subordinate clause: II jurait qu' il
ne se rendrait (conditional instead of future) jamais coupable
d'un tel crime. The same can be used indicatively: Je ne
me rendrait jamais coupable, etc. As tvuerde gehen is noth¬
ing else than an absolute future conditional, so the French
conditional "Je dormerais" denotes no definite time, no pecu¬
liar mode, but on^ such a subjunctive as is used conditipnally
and optatively. While the Indicative of the Imperfect is lost
in the dialects of Upper Germany and the periphrastic Pre¬
terite ( Perfect) is used for it, the Subjunctive of the Imper-
58
Colorado College Studies.
feet is retained with the conditional force. One can hear in
theWestern Alps ( Switzerland ) the periphrasis with "i wurdi,
wurd (wur)," in the Eastern, more often the periphrasis with
"i thaet", but also the weak and sti'ong forms of the Imper¬
fect Subjunctive.
Vernalaken explains the origin of the future signification
of rrerden as follows: Sein and werdcn with the present jiarti-
ciple are analogous to s^ein and ircrdcn with the infinitive,
though this construction with sein is considerably older than
with ircrden (cf. Grimm, Gr., 4,125; for an example of werdcn
with the present participle compare die werdent (joi sehende).
With both auxiliaries the infinitive soon replaced the parti¬
ciple; the present of iverden joined to the infinitive was quite
suitable to denote the present as initial point of the future
(that is the inception of the action); for the transition was
very near. We find this already prepared in the 13th and 14th
centuries, when the periphrasis with sollen was gradually dis¬
appearing. The passive periphrasis with trerden may properly
be connected with this (cf. Grimm, Gr., 4,182). The M.H.G.
furnishes examples like ich waene ir werdent mivs jehen, daz
ir iuch Koufes nit begant, Flore 3115; Der icfrf iuch wol
enthatten, ibid. 3580. In the 15th century the future signifi¬
cation of the present of iverden became more decided, e. g., so
wird in Jhesus wisenj Wann er umb sich bin und her sehen
wuertj Wann dann der sudenwind ungestuemlichen ween
ivuerd (spiret), so godt dann die gezierd in doernen hinweg
(anfaengt zu wehen). Toward the end of the 15th century the
vacillation between the participle and infinitive was greatest,
but finally the infinitive carried the day (cf. sie iverdent wisheyt
sehen ah und den Ion, der drumb ist bereit und werend ivurt
jn ewikeyt).
If we now turn to the past tense, we shall find the same
idea of inceptive action expressed by the past tense of iverden,
at first joined with the participle and then with the infinitive,
e. g. do sie got an sehende ivurden (cf. above, die werdent got
sehende); Sie ivurden lihte spotten min; Und da bi wart man
sie erlcennen ("this led to their recognition"); So wanne si
dat kint an sach, so wart si iveinenj again, gar haisz sy wainen
The Conditional in German.
59
icard ("she began to weep bitterly"); even in the 16th cen¬
tury it retained this signification, e. g., nnd als er schneiden
solt und die scher nit enfand, icard er ueber sich sehen und
uff die bueni klopffen mit den henden ob er die scher nit
hoerte; do er sich weret und schryen ward, schluogen sie, etc.
Vernalaken, I, 29 ff., has any number of examples all of which
show that this verb then denoted the beginning of an action,
as may be seen from those already given.
For a complete understanding of these periphrastic forms
we lAust carefully consider the predication, or predicate, where
it will be necessary to distinguish beginning, middle, end,
duration and repetition of the action and for all three tenses.
The inception or beginning of an action always has the ac¬
cessory idea of ivill, of intention, and is frequently denoted in
language by periphrasis (cf. Grimm, Gr., 4,182), especially by
sollen, wollen and werden. Compare for instance the Latin
hortaturus sum, cram, era, French aller with the infinitive,
English going to denote the future, etc. Naturally these peri¬
phrases acquire certain other accessory ideas which are more
or less independently developed in each language. Other
periphrases of this nature will readily occur to all. Let us
now examine more closely the exact shade of thought that
these auxiliaries were and still are, to a certain degree, in¬
tended to express. For besides will and intention they also
expressed duty, and language is constantly enriching itself
with expressions that convey to the mind those various shades
of thought relating to the future. What peculiar shade of
meaning is there, then, in these auxiliaries that led to their
use for expressing future time?
The Gothic, Isidor (8th cent.), Otfrid (9th cent.), and
Notker (10th cent.) did not employ werden as future aux¬
iliary. They in common use the pi'esent as future, or when
they wish to distinguish the future they use the auxiliary
sollen ( Ulf. Mc. 8th, 31; jah dugann lais jan ins thatei skal
sun Us mans filu finnan; hva skuli thata barn wairthan? Sei-
inon, skal thus hva qithan, ith is qath: laisari, qith. Otf. 1,23:
Thu scalt beran einan, etc.; 17, 4: seal ih iz mit uuillen,etc.).
The A.S. also uses the present as future, but when the addi-
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tional idea of duty and intention is to be expressed it employs
sceal and wille (cf. Fr. il doit arriver, er wird ankommen).
Notice furthermore the Gothic sa auk habaida ina galewjan
ains wisands thize twalibe (is eum proditurus erat, Jno., 6,71;
also 12, 26: tharuh sa andbahts meins wisan habaith).
We cannot, however, consider the absolute temporal rela¬
tions of the present, the past, and the future without at the
same time discussing those of inception, completion, duration
and repetition of the action, though we are here only con¬
cerned with the inceptive action and the modal relations, to
which we shall confine ourselves. In A.S. gann ( began) has
an inceptive force, e. g., ic gann drinkan (cf. I am going to
write, je vais boire, mod. Eng. begin, Lat. coepi, etc.). In
German the future formed by sollen and wollen corresponds
to this French je vais vous dire, j'allais partir and the Eng¬
lish I was about, was going to do it, rather than to the Latin
periphrastic future. In Gothic we find only one form with
sollen, saei skulda qiman (Matt. 11, 14, qui venturus erat),
which seems to correspond more to the periphrastic future of
the Latin. Though sollen and tvollen per se express modal
relations, they, however, have an inceptive signification in
such expressions as, Es will regnen. Die Wunde will heilen,
Es sollte eben getanzt werden, als, etc., Der Tisch soil gerade
gedeckt werden, just as much as the French and English
forms cited above. A relative temporal relation to a preceding
event is inceptively denoted by the Imperfect, e.g., DieWunde
wollte eben heilen, als sie wieder aufgerissen wurde, DerVer-
brecher sollte ebep hingerichtet werden, als die Nachricht
von seiner Begnadigung ankam. Before proceeding farther
we shall have to discuss the modal signification of these aux¬
iliaries in order to determine why and when they should be
used and how their modal and inceptive signification led to
their future use until differentiation settled modern use.
A real necessity, that is, a necessity imposed upon matter
by nature, is expressed by mnessen (vacare; cf. Musse, mues-
sig). A moral necessity imposed, not by the will of the in¬
dividual but by a general law, is not different from a real
necessity, and is therefore likewise expressed by 7nuessen,
The Conditional in German.
01
e.g., Alle Mensclien muessen sterben; Man muss der Obrig-
keit gehorchen. A moral necessity is expressed by sollen and
wollen. Sollen (debere), which in Gothic and O. German
very frequently denotes the temporal relation of the future,
has in Gothic the above mentioned signification of muessen,
e. g., Tharuh is qath du im thatei jah thaim antharaim baur-
gim wailamerjan ik skal bi thiudangardja guths, unte duthe
mik insandida. Luc. 4,43; unte thatei skuldedum taujan gata-
widedum. Luc. 17,10; Qathuth than jah gajukon im du tham-
mei sinteino skulun bidjan. Luc. 18, 1; ik skal waurkjan
waurstwa this sandjandins mik. Jno. 9, 4; jah bi thamma
witoda unsaramma skal gaswiltan. Jno. 19, 7: in presnt use it
denotes the moral necessity only in so far as it is imposed by
the will of another, by command. Every sollen corresponds
to a wollen, e. g., Du sollst schweigen (Ich will es), Ich soil
kommen (Er will es). Wollen denotes the moral necessity
in as far as it is imposed by the will of the predicated agent.
The action denoted as necessary is either the action of the
Ijredicated (willing [ participle] ) agent, e. g., er will sprechen,
or the action of another agent, e. g., Er will, dass ich spreche.
As the English uses these auxiliaries for the temporal rela¬
tion of the future it must use other auxiliaries (I wisli, I
mean, I intend, etc.,) to express these relations.
These same three auxiliaries, muessen, sollen, wollen, like¬
wise represent the logical necessity with various shades of
meaning. Like Iwennen, duerfen, moegen, they are also em¬
ployed in the present in the sense of a logical possibility,
even when the declaration of the predicate is past; or in the
imperfect when the declaration of the predicated agent is
placed in the past, e. g., Er will ihn gesehen haben, Er wollte
ihn gesehen haben. Muessen denotes the pure logical neces¬
sity as one imposed by the judgment of the speaker himself,
e. g., Er muss krank sein. Sollen denotes the logical neces¬
sity imposed by the judgment of another and corresponds to
the Latin decor,e. g., Er soli krank sein, Ich soil das gesagt
haben. Wollen denotes the logical necessity imposed by the
judgment of the predicated agent, e. g., Er will dich kennen,
er will dich oft gesehen haben (asserts). Moreover it often
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denotes that the judgment of the predicated agent and the
logical necessity thereby imposed is only pretended, e. g., Er
will unschuldig sein (he pretends to be innocent), Er will
kuenftige Dinge wissen ( he pretends to know future things).
It is well known that language often represents the rela¬
tion of necessity as a temporal relation, though more often it
employs the temporal forms of the future. On the other hand
the temporal relations of the future are often expressed by
those auxiliaries which denote necessity, especially by sollen
and wollen. It must be remembered that the fine distinction
now observed in the use of shall and will did not exist in
A.S. where the employment of these verbs corresponded more
to that of the German verbs. In German the future is very
often denoted by ivollen and in restricted (not free) actions
by sollen. e.g., Ich will dich morgen besuchen; 1st es wahr,
dass mir ein Tag zwei Soehne rauben soil? By means of
ivollen and sollen partly inceptive forms and partly temporal
forms are created, the former of which alone concerns us here,
as they form a strong basis for the future element of these
verbs (cf. above).
Thus we see that however poor the German is in forms for
future time, it is rich in expressions of will, intention, duty,
and necessity. Sollen is least of all employed to denote mere
future time in modern German, though it is on the other hand
used imperatively, which always has reference to future ac¬
tion: ihr sollt kommen! ihr sollt mir willkommen sein! Wol¬
len denotes rather the free decision and belongs preferably
to the first person, sollen to the second, to which the impera¬
tive refers, while werden denotes the pure, abstract future and
belongs to the third person.
i
To return, after this digression, to the two prevailing
opinions in regard to the origin of the conditional forms in
German we have: 1st, that of Grimm, that the present of the
Conditional (kame) in the verbs of the new conjugation (re-
dete) in German is not different from tUe imperfect Indicative
and this caused the introduction of the future form (wurde)
to supply the place of the failing subjunctive form; secondly,
the inceiitive preterite (ward weinen) is employed later as
The Conditional in German.
conditional Subjunctive because it expresses just what the
Conditional Mode should express. By Conditional Mode I
do not mean Conditional form, for we have several forms to
express the same idea, but the peculiar mode of thougtit
which these various forms all more or less distinctively con¬
vey to the mind of the hearer or reader. What is the truth in
regard to the matter? In other words, what do we mean by
Conditional Mode? These are questions that cannot be an-
swei'ed until we consider the various modes of thought and
their form of exxiression. Then we can resume our considera¬
tion of the origin of the two conditional forms wnrde lichen,
wurde gelieht hahen and show the gradual differentiation in
the meaning of sollto, wollte and wurde, giving; the reason for
present usage. Let us then briefly consider the different
modes in their relations to, and differences from, one another.
The Indicative expresses the simple thought of the speaker
which corresponds exactly to the reality, while the Conditional
expresses a thought which corresponds to a reality only as¬
sumed for the time being by the sxjeaker. The Subjunctive
also expresses a thought, but only as considered by the speaker.
Generally speaking, the Indicative and Conditional are the
modal forms for judgments of the speaker, and hence the
riiodal forms of independent clauses, whereas the Subjunctive
is the modal form of thoughts which represent, not the judg¬
ment of the sj^eaker, but a thought considered by him; it is
therefore the modal form of dependent clauses.
Following the example of the Latin Grammar the German
Grammar did not distinguish the Conditional as a special
mode in earlier times, but included it, inasmuch as it is formed
from the past tense-forms, among the tense-forms of the past
Subjunctive. If we examine the signification of these forms,
we must distinguish the Conditional, if we have any decided
idea of modal relations at all, as that form of a conceptive
thought which assumes something contradictory (antitheti¬
cal ) in its very nature, from the Subjunctive, as that form
of thought whicTi is only contemplated. Several older Latin
and German grammarians, following the example of the
Greeks, have really distinguished the Conditional as a special
()-i
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mode from the Subjunctive. The simple forms of the Con¬
ditional, c. (]., spraeche, haette gesj)rochen, ai*e formed, like
the forms of the Subjunctive, from the tense-forms of the
Indicative; but they by no means correspond in meaning to
these latter forms; in time spraeche does not correspond to
sprach, but to the present spreclie; and haette gesprochen
not to the pluperfect hatte gesprochen, but to the perfect habe
gesprochen. This is also the case with the Latin conditional
forms, c. (J., (lircrem, (nnarcm, dixissem, (imavisscm, yet with
the difference that dicerem, (imarem, etc., are not formed from
the preterite of the Indicative. The modal relation of the
Conditional—the assumed reality of a predicate which is not
real in itself for the speaker—is a special relation decidedly
different from the modal relation of the Subjunctive—a re¬
lation merely contemplated by the speaker, and therefoi-e for
him only a logically possible thought; in all languages, there¬
fore, it is distinguished in form from the relations of the Sub¬
junctive. All languages have not, indeed, like the Indie,
Greek and German languages, special flexional forms for this
modal relation. The Slavic, as well as the Semitic languages,
have no special form for the Conditional, just as they have
none for the Subjunctive; they none the less express both
modal relations and clearly distinguish them by denoting tlie
relation of the Subjunctive by the tense-forms of the future,
but the Conditional by the tense-forms of the preterite. Thus
the logical possibility ( Subjunctive) is represented as some¬
thing which can become real, and the reality which is only
assumed (Conditional) as something that has been and there¬
fore is not real. The Conditional is often represented both
in Greek and German in the same way, e. g., r: ididou ay,
wenn er etwas haette, so wuerde er es geben; Maria Stuart
war noch heute frei, wenn ich es nicht hindert; Wenn dieser
starke Arm Euch nicht hereingefuehrt, Ihr sahet nie den
Kauch von einem fraenkischen Kamin steigen. It is es¬
pecially the negatived reality which language represents by
using a preterite tense instead of the Conditional; the latter
(negatived reality) is often denoted by a mere preterite, c.//.,
Jene hat gelebt, wenn ich dies Blatt aus meinen Haenden
gebe. Notice the following in Greek where the particle av
The Conditional in Geeman.
65
marks an action as contingent on an unfulfilled supposition,
and therefore contrary to fact (hypothetical Indicative; Had-
ley Sec. 895): e3wxsv av, d tc er/sv, "he would have given, if he
had had anything". Sometimes in the conclusion the aorist
refers to the present and is used of the inception or bringing
about of the action, e. g., si iyu* as iruyyavox ~i av pm
ar.sxpbut, "if I happened to be asking you, what loould you
(proceed to) answer?''''
On the other hand every thought of cognition-^a judg¬
ment or a question—is either a logically real or a logically
possible thought. We call it logically real when it is an in¬
tuitive thought of the speaker; we call it logically possible
when it is a thought intuitively conceived by the speaker and
is assumed as a grammatical member in an intuitive con¬
ception. The intuitive thought of the speaker is expressed
in an independent clause, e.g., Er hat immerWort gehalten.
From those intuitive thoughts which are really in the rela¬
tion of logical reality we must distinguish those intuitive
thoughts in which the predicate stands in an antithesis to
the reality merely assumed by the speaker, e.g., Jedermann
wuerde ihm vertrauen, wenn er immer Wort gehalten haette.
The intuitive thought of the speaker is expressed, when it
really stands in the relation of logical reality, by the Indica¬
tive; when the predicate of the thought stands in an antithesis
to the reality assumed by the speaker, it is then it is expressed
by the Conditional. The one common point which the Con¬
ditional has with the Indicative is that it expresses a real
judgment—an intuitive thought—of the speaker, and hence,
like the Indicative, stands in independent clauses; it is dis¬
tinguished from the Indicative by always representing the
predicate in the relation of a reality, though only assumed by
the speaker. The sentence Waere er ein guter Haushaelter
gewesen, so waere er der reichste Mann in der Stadt expresses,
just as Wenn er ein guter Haushaelter ist, wird er ein reicher
Mann,* or Er ist der reichste Mann im Lande, a real judgment
of the speaker, though the predicate is not, as in the last sen¬
tence, in the relation of unconditional reality, but the reality
of the predicate is conditioned, and, indeed, so conditioned
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that it is not thought of, as in the second sentence, in the re¬
lation of possibility, but with condition at the same time in
the relation of negative reality; the reality of the conditioned
conception, like that of the condition, is only assumecf by the
speaker. Since the condition expressed in the dependent
clause likewise stands in the relation of a negative reality, it
is also expressed by the Conditional. We must take that sig¬
nification which the Conditional has in the independent clause
as the real fundamental signification of this modal form. For,
though the Conditional is used in dependent clauses, aside
from the case of a merely assumed condition just mentioned,
it assumes the signification of a Subjunctive by representing
the relation of a logically possible thought in the form of an
assumed reality. We must, however, distinguish this deriva¬
tive signification of the Conditional from its fundamental sig¬
nification. The Conditional stands much nearer the Indicative
in its fundamental signification than it does to the Subjunc-.
tive, as is seen from the fact that it frequently exchanges with
the preterite of the Indicative in the ancient and modern lan¬
guages without varying the signification in the least, e. g., st
Ti slyov, iSiduiv av. Moreover in many other relations, and es¬
pecially in hypothetical sentences, the Conditional is also just
like the Indicative. In hypothetical sentences, where the re¬
lation of a necessary condition is to be expressed, either with
the Conditional or the Indicative, the Greek uses si and not
as with the Subjunctive, e. g., El Osdoc/xev (tzotzsTv rd? ^uaeci; rd?
Twv eupij(Tu/j.sv. Cf. with this the German: Haett' er
meip Auge, oder stuend' ich oben, das Kleinste nicht entginge
meinem Blick; O waerst Du wahr gewesen und gerade, nie
kam es dahin, Alles stuende anders.
The meaning of the Conditional explains why its forms
are derived from the forms of the preterite and why languages
which lack the special modal forms of the Conditional use a
preterite of the Indicative instead. If we must assume that
language did not originally positively distinguish the modal
relations from the relations of time and represented the re¬
ality as present in time and the other modal relations as rela¬
tions of time not present, it is then natural that language
The Conditional in German.
67
should represent the relation of a negatived reality by that
relation of time which denied most decidedly the reality in
time (present): viz., by the past. Grammar especially should
consider speech-forms, not according to the relation of the
outer form, but according to their signification; it should
therefore present the forms of the Conditional, not as the
Latin Grammar, and following this usage the German Gram¬
mar earlier, as tense-forms of the Subjunctive, but as special
modal forms. In the dependent clause the use of the Con¬
ditional is like a preterite of the independent clause, but it
has here, as above stated, lost its fundamental meaning. The
fundamental idea of the Conditional excludes time altogether,
or at least distinguishes time less than any other mode. The
same tense-forms of the Conditional, though derived from a
preterite tense-form, denote, with more freedom than the
present of the Indicative, present and future time, e. g.,Waere
er (jetzt) krank, so arbeitete er nicht (or, so wuerde er nicht
arbeiten); Wenn er morgen kaeme, waere er mehr willkom-
men sein, als heute (or wuerde er mehr willkommen sein);
Utinam eras veniretl It is remarkable in this respect that
the O.H.G. had only one form of the Conditional to express
not only the present and future but also the past, e. g., Ni
wari tho thiu giburt, tho wurti wprolt firwurt; sia satanas
ginami, ob er tho ni quami; Oba er (Adam) iz firliazi, odo iz
got biliazi, ouh worolt ni gigiangi in thesa goringi (Otfrid).
Even in dependent clauses where the Conditional assumes the
signification of the Subjunctive, the present also expresses
the past, e.g., Ouh n' ist, ther er gihorti so fronisg arunti;
n' ist wib, thaz io gigiangi in merun goringi; Thaz thu unsih
nu gidua wis, oba thu gotes sun sis, zi kriste er thih ginanti,
ioh hera in worolt santi (Otfrid). The periphrastic Condi¬
tional (ich wuerde sprechen) cannot therefore be found in
O.H.G. because in O.H.G. the future of the Indicative is not
at this time formed by werclen. Thus in dependent clauses
where the Conditional has the signification of the Subjunc¬
tive and where we in general express the future by a future
form we always find the present in O.H.G., e.g., Ther gotes
geist, ther mo ana was, ther gihiaz imo thaz, thaz krist er
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dniagi in henti er sines dages enti, er todes io nf koreti, er er
den drost habeti (Otfrid ).
In Mod.H.G., however, besides the present ich spraeche,
and the preterite ich haette gesprochen, the Conditional also
has a future ich wuerde sprechen and a future perfect ich
wuerde gesprochen haben, as we now call these forms. But
these futures, if they are used in the real signification of the
Conditional, do not have the temporal (tense, time) significa¬
tion corresponding to the form of the simple future; for the
future is not distinguished from the present, and the future
perfect from the preterite, e. r7.,Waere er abgereiset, so wuesste
ich es, or, so wuerde ich es wissen; waere er eingeladen wor-
den, so waere er gekommen, or, so wuerde er gekommen sein.
Only when the futures stand in a dependent clause and have
the signification of the Subjunctive do they denote the tem¬
poral relation corresponding to their form, e.g., Ich hoffte,er
wuerde kommen; Er sagte, er wuerde kommen, instead of er
werde kommen; Er glaubte, er wuerde die Arbeit schon vol-
lendet haben, ehe du abreisest. The use of the future per¬
fect, as in the Indicative, is here also very limited. In the
real signification of the Conditional the futures are used only
in the independent clause, e. g., Waere er nicht krank, so
wuerde ich ihn besuchen; haette er den Brief geschrieben, so
wuerde ich ihn erhalten haben. The Romance and English
languages, which in other respects express' the relation of the
assumed reality by the preterite, of the Indicative, generally
use in the conditional sentences a form of the future, e. g., s' il
avait faim, il mangerait; s' il le savait, iWous I'auraitdit; If
I were thisty, I should drink.
The use of the forms of the future here (in the cases we
have just explained) has its justification in the special rela¬
tion of the conditional sentence as a causal relation. For in
truth the conditioning thought is conceived as a possible rea¬
son and the conditional thought as that caused by the reason;
thus here the condition is represented as something following
in time the conditioning thought and as something future in
reference to the conditioning thought. We can furthermore
add to this also that the relation of possibility expressed in
The Conditional in German.
69
the conditional sentence is very frequently represented by the
temporal relation of the future. This relation of reason is
really at the same time a temporal relation, if it is a real one.
We therefore make a special use of these forms of the future,
whenever the possible reason (the condition) is to be repre¬
sented as a real one (not as a logical one). Thus we say,
e. (/., Wenn er Wein getrunken haette, wuerde er berauscht
sein; wenn es warm waere, wuerde das Eis schmelzen, but
never Wenn er berauscht waere, wuerde er Wein getrunken
haben; Wenn das Eis schmoelze, wuerde es warm sein. The
real signification of the Conditional is the fact that it serves,
like every abrogative antithesis, to emphasize the thought pre¬
sented. (Cf. Dr. K. F. Becker, Ausf. d. Gramm., II, p. 58ff.,
from whom most of this discussion is taken.)
If we now compare the various significations of these modes
with those which obtained in the older languages, we shall see
that the germ of even the nicer shades of distinction existed
at that early day. The future forms also existed and are de¬
scribed by Whitney, Skr. Gramm. Sec. 940 as follows: "From
the future-stem is made an augment-preterit, by prefixing the
augment and adding the secondary endings, in precisely the
same manner as an imperfect from a present-stem in a. This
preterite is called the conditional.
"It stands related to the future, in form and meaning, as
the French conditional aurais to the future aurai, or as the
English would have to tvill have—nearly as the German
wuerde hahen to werde haben.''''
It is, however, the rarest of all forms of the Sanskrit verb,
theR.V. containing but one example, abharisyat," was going to
carry off,'' and the later literature not many more. Whitney
defines the Conditional thus: "The conditional would seem
to be most originally and properly used to signify that some¬
thing 'was going to' be done. And this value it has in its only
Vedic occurrence, and occasionally elsewhere. But usually
it has the sens% ordinarily called 'conditional'; and in the
great majority of its occurrences it is found (like the sub¬
junctive and optative, when used in the same value) in both
clauses of a conditional sentence. Thus, j6 vrtrdya sinam
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6trd 'bharisyat prd tdm jdnitri vidiisa uvaca (K.V,), 'him,
who was going here to carry ofif Vritra's wealth, his mother pro.
claimed to the knowing one'; catayum gam akarisyam (A.B.),
'I was going to make (should have made) the cow live a hun¬
dred years.'" (Sec. 950.)
Of the other three modes. Subjunctive, Optative and Im¬
perative, but little need be said. The Subjunctive proper
early became nearly extinct. "Its fundamental meaning,"
says Whitney, Sec. 674, "is perhaps that of requisition, less
peremptory than the Imperative, more so than the Optative."
The Optative soon replaced it. Command, requisition, wish,
with no sharp line of division between, would characterize the
shades of thought expressed by these three modes. Whitney
says they may all be specialized uses of forms originally
equivalent—-having, for instance, a general future meaning.
"This, however, (in Skr. as in other languages) is by no
means always of the same force; the command shades off into
a demand, an exhortation, an entreaty, an expression of an
earnest desire. The Imperative also sometimes signifies an
assumption or concession; and occasionally by pregnant con¬
struction, it becomes the expression of something conditional
or contingent; but it does not acquire any regular use in de¬
pendent clause-making." ( Sec. 572.)
As our desires naturally find utterance in the form of a
request or an entreaty, the Optative often becomes a mild
Imperative. It can also express what is generally desirable
or proper, or what should or ought to be and thus become the
mode of prescription. It may also weakly signify what may
or can be, what is likely or usual, and thus become a softened
statement of what actually is. " In dependent clauses, with
relative pronouns and conjunctions, it becomes a regular
means of expression of the conditional and contingent, in a
wide and increasing variety of uses. Thus, in A.V., we have
in imp.: cat4m jiva carMah,' do thou live a hundred autumns';
ubhau tau jivatam jarddasti, 'let them both live to attain old
age';—in subj., adyd jivani, 'let me live this day'; catam
jivati car4dah,'he shall live a hundred autumns';—in opt.,
jtvema carddam catdni, 'may we live hundreds of autumns';
The Conditional in German.
71
sdrvam &yur jivyasam (pre.), 'I would fain live out my whole
term of life'. Here the modes would be interchangeable
with a hardly perceptible change of meaning." ( Sec. 573ff.)
In many of its uses the Optative takes the place of our Con¬
ditional and it has one other characteristic like it, viz., its use
in conditional clauses contrary to fact.
If we consider the use of old prose in Greek and compare
the usage of the Greek aorist, we cannot doubt that the usage
of the Indie aorist extends back to a time of the inceptive
action. Bartholomae asserts that the Iranian aorist does not
essentially differ from the Greek aorist, only that the Iranian
still denotes by the imperfect one part of what the Greeks
express by the aorist. It is therefore probable that the Greek
aorist in the main corresponds to the Indo-Germanic aorist,
though varying here and there in its final development. But
the Indie aorist expresses the inceptive action in nearly every
case and this use is found in Greek oftener than one would
suppose from the statements of the grammarians. Naturally
the " now" does not inhere in the aorist, but is expressed by
a particle like vuv, e. g.,
Zsu<s //.£ iiiya Kpovidrj^ arj ividrjns j^apeirj,
S? -p\v ixiv pot VTrifT^sTd xai xaTs'vetjTsv
"Jz-tov ix-ip<TavT suTsi^sov d^oxieaOac^
vuv Si xaxypx d-dzrjv pouZsbaazo.—B 114.
p.yj [IS, yuvai^ yaXeztdiaiv oveiSeai Oopov k'wiKze.
vuv piv yap lUeviXadis ivixTjuev ahv 'AOrjvip
xeivdv 5'aar:? iyw.—F 439.
"In the conclusion, the aorist sometimes refers io present
time, being used of the inception or bringing to pass of the
action, e.g., el tyw ae izuyya.vdv dvspwzwv, zi dv pdi ar.sxptvo), "if I
happened to be asking you, what would you (proceed to)
answer?", Had. Sec. 895. In Indo-Germanic, then, we may
conclude that the aorist-stem marks the inceptive action,
which the Indicative transfers to the past; the distance of
the time from the speaker was not indicated. Of. Delbruck,
Griech. Synt., p. 107. The aorists are frequently translated
by the present in colloquial style, e. g., vuv S£ aeu mvdaap.-r^v
72
CoLOEADO College Studies.
■Kay-J^u (ppiva<s {P.173)\ rj<r0rjv,i7:Tijve<Ta, iyiXaaa, etc., are so trans¬
lated.
The Subjunctive and Optative aorists are modes of the
inceptive action, nothing else; they do not there contain a
single sign of temporal gradation, nor do they have either in
Sanskrit or Zend a temporal sense, and just as little in the
independent clauses of the Greek. In the developed sen¬
tence of the Greek, however, their surroundings are such that
the sense of the past time enters, or seems to enter into them,
which is specially true in the following cases. In prior rela¬
tive and conjunctive sentences the Subjunctive aorist seems
to have the sense of past time, e.g., 3? ph i3dX^ rpTjpwva -jtiXsiav
TTavra? asipd/xevo^ KsXixeai; olxuxds <pepi<yO(u. W 855. All the sen¬
tence means is "whoever shall hit the dove". The hearer
will understand the hitting precedes the prize. Pedantically
we might translate "whoever shall have hit", though the
future perfect does not inhere in the aorist, but is transferred
there by the hearer from the context of the aorist. In such
surroundings the aorist is nearly always chosen because the
inception of the action is emphatic, not its course. The Skr.
does not distinguish action so accurately as the Greek and uses
the present in similar cases, and this was very probably done
in Greek also in colloquial style. "When the Optative is in
the dependent question, it does contain the sense of the past,
e. g., iTceipdtza^ riva dsozspov /j.ez' ixsTvov 7^()^ ■ meaning "whomever
he might have found." However this sense does not belong
to iSot as such, but only in so far as it is the representative of
an side?. From the sentence ec zixa sldss we have by means of
the transmutation of persons and modes ec zcva tdoi and in the
transmutation the temporal sense of the original el3s? is trans¬
ferred to cSot. This transmutation finds moreover no analogy
in the Indie group, but is a special development of the Greek.
(Cf. Delbruck, Griech. Synt., p. 107 ff.)
The results of our investigation so far are then that the
Conditional is the form of a conceptive thought which as¬
sumes something contradictory (or antithetical) in its very
nature. Its modal relation—the assumed reality of the predi¬
cate, which is not real in itself for the speaker—is a special
The Conditional in German.
73
relation essentially difEerent from that of the Subjunctive
proper. It represents the assumed reality as something that
has been and therefore not real, that is, a logically possible
thought intuitively conceived by the speaker and forming a
grammatical member in an intuitive conception. Its real
significance is that it serves, like every abrogative antithesis,
to emphasize the thought presented, especially when the In¬
dicative form is used. Its most original signification would
seem to be "was going to", or "is going to" be done. We
have furthermore seen that the Indo - Germanic aorist ex¬
presses the inceptive action in nearly every case and that
this use is also found in Greek. "In the conclusion the aorist
sometimes refers to present time, being used of the inception,
or bringing to pass of the action." The inceptive action leads
gradually to the future idea, and, if Whitney is right in his
conjecture that the Imperative, Subjunctive and Optative
"may all be uses of forms originally equivalent—having, for
instance, a general future meaning"; if, moreover, our ex¬
planation of the use of the future forms in the special relation
of the conditional sentence as a causal relation (see above,
p. 68,) is true, then it is easy to understand the use of the
different forms, both simple and periphrastic, to express the
modal relation of the Conditional. For the inception of the
action always has the accessory idea of will, of intention, and
is denoted by periphrasis, especially by sollen, wollen, werden.
Of. the Latin hortaturus sum, eram, era, etc. In order to
express this modal and inceptive shade of thought (just given
in summary) which we have concluded to call "conditional"
par excellence, the German language has used various forms,
simple and periphrastic. In O.H.G., as we have seen, the
preterite form (the so-called imperfect Subjunctive) was al¬
ways used. Later in the development of the language, as the
endings wore away and the different forms were no longer
distinguishable, sollen, wollen, and werden were used. Let us
turn to these auxibaries and consider the appropriateness of
each for expressing this conditional thought. Their use to
express future time has already been stated. To this we can
add that werden is surer, the speaker accepts the news as his
own, e. g., Der liebe Gott wird uns helfen; er theilte ihr mit,
74
Colorado College Studies.
er wolle Unterkommen suchen, sie alsdann abholen, und er
hoffe, sie werde ihm ihre Hand nicht versagen. The same
confidence lies in sollen, e.g., Sie riefen hoehnisch aus: die
sollen mir nicht entwischen; more emphatically, Der Brief
soli Morgenabend mit der reitenden Post abgehen; Es soil
das naechste Mai geschehen, etc. Sollen is besides used to ex¬
press the conditional idea, e. g., Sollte ich mich irren? Wenn
er kommen sollte. However, this use of the modal auxiliaries
to denote the modal relation of the predication in German is
far less frequent than in languages which have no complete
modal flexions, as the English, which always expresses the
Conditional in independent clauses by auxiliaries, e. gr., "I
should have sent you the book, if I had known that you would
be at leisure to read it".
In an earlier stage of the German language sein with the
present participle paraphrases the incomplete tense of the
active and werden was also soon used in the same manner.
The former combination denotes the duration of the action,
while the latter mostly denotes the inception of the action.
Soon, however, the present participle became the infinitive
both with sein and werden. In Mod.H.G. only a few examples
are left with sein, but it is the only construction with werden.
This inceptive force of werden, that is, the Werden des Zu-
standes, was quite common in Mid.H.G., e. g.. Wan si noch
hinaht swanger wirt und einen sun wirt tragende, etc. The
future idea comes very near this, so that the employment of
werden with the present participle to express future time is
in Mid.H.G. the usual form, though sollen and wollen were
also used. It is the continuation of the inceptive force of
this combination and was replaced by werden and the infini¬
tive when the infinitive crowded out the present participle.
As we have seen above the preterite of iverden and the infini¬
tive (earlier present participle) retained still later than the
present its inceptive force. In the 13th cent, it is common,
e.g., daz wart in tragen sit; daz Morice na der art wahsen an
dem kinde wart; der kunic wart si vaste klagen, etc.
We have now arrived at that point of our investigation
where we can roughly state the cause of the differentiation of
The Conditional in German.
75
the different auxiliaries. Naturally certain accessory ideas
join themselves to the periphrases which are developed in
every language for increasing the number of ways of express¬
ing the different shades of thought. In sollen we have the
accessory idea of necessity, of must; in wollen, the inclination,
the determination of the agent. Cf. the English shall, will.
In werden we have at first the idea of the inception of the
action, later the pure future idea. This differentiation had
already begun when the language, on account of the loss of
the endings, was seeking a modal form i o replace the fast dis¬
appearing conditional form, especially in the weak verbs (re-
dete) where Indicative and Conditional were indistinguishable.
Sollte and wollte, both of which had a general future mean¬
ing, perhaps a common quality of the Imperative, Subjunctive,
Optative and Conditional and logically based on reason, as we
have seen above, were often used to supply this modal form
of thought. In the strong verbs, and in other verbs also
where the form was distinguishable, the real conditional form
was retained. Sollte and wollte soon fell into the same cate¬
gory as redete, which could not be distinguished from the
Indicative as a conditional form; but the peculiar appropri¬
ateness of werden to express the true modal relation of a
Conditional was recognized and replaced nearly all other peri¬
phrastic forms. Sollen is still used, as we have already stated,
though with a slightly different shade of meaning.
Present usage presents two phases of the Conditional
(kaeme, gaebe, wuerde kommen, wuerde geben and their com¬
pounds); it is used in the independent and in the dependent
clause. It stands in the purely hypothetical period (protasis
and apodosis) and both forms (simple and periphrastic) may
be used and are often interchangeable, though the simple
form is much more frequent than the periphrastic. But it
must be remembered that these two forms are not absolutely
identical in sense. The periphrastic form may sometimes be
preferred where the idea of futurity is prominent, e. g., lebtest
du noch, so wuerde ich dich von dieser Zeit an lieben, "wert
thou still alive, I should love thee henceforth." Again for
formal reasons where the simple form would not be distin-
76
CoLOEADO College Studies.
guisliable from the indicative form (as in redete) the peri¬
phrastic form is preferred.
In the dependent clause present usage is unsettled; the
real Subjunctive is often used where the Conditional (both
forms) ought to be used. But whenever the reference to the
future is plain, then the periphrastic conditional form is pre¬
ferred, e. g., er wusste, dass diese Anerbietungen den Kreuz-
zug nicht aufhalten wuerden ( for werden, which would not
be distinguishable from an Indicative), "he knew that these
offers would not detain the crusade."
(Colorado (College,
Colorado Spriipgs, Colo*
■'T^'HE College offers two courses, leading, respectively, to the
^ degrees of Bachelor of Arts and Bachelor of Philosophy.
In the Ph. B. Course, Greek is omitted and more attention
is given to the sciences and modern languages. The College
has a good library and well-equipped laboratories.
The various courses of study have now been so arranged
and the faculty so enlarged that Colorado College offers the
same educational facilities as the Eastern colleges.
For catalogues, address t-.
^ ' Wm. F. Slooum,
President,
oa
The Cutler Academy,
Under the auspices of the Colorado College, gives students
a thorough preparation for admission to the Freshman class
of any college in the country. Correspondence concerning
the Cutler Academy should be addressed to the Assistant
Principal, Augustus T. Mueeay.
The Location of the College is unsurpassed. Colorado Springs has
a world-wide reputation as a Health Resort.
Students forced by pulmonary or malarial troubles to
discontinue their studies in the East, pursue college courses
here successfully and at the same time make a permanent
gain in health.
^■IL— ,:-j3
- KKa-JSH-
r7 As.
FOURTH ANNUAL PUBLICATION.
Colorado College
VI
Studies.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY. ^
COLORADO SPRINGS, COLORADO.
1893.
THE GAZETTE PRINTING COMPANY,
COLORADO SPRINGS, COLO.
FOURTH ANNUAL PUBLICATION.
Colorado College
• »
, Studies.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLORADO.
1893.
THE GAZETTE PRINTING COMPANY,
COLORADO SPRINGS, COLO.
318-1
Officers, 189^.
President, William Stkieby.
-r. • 1 X (W. P. Mustard.
Vice-Presidents, - - - - - -
(L. R. Ehrich.
Secretary, - Florian Cajori.
Treasurer. -------- Frank H. Loud.
PLACE OF MEETING,
Palmer Hall, Colorado College.
CONTENTS.
PAGE.
Announcement, 4
The Circular Locus, - - - - 5
F. H. Loud.
On the Eight Lines Usually Prefixed to Horat. Serin. 1.10, - 31
W. P. Mustard.
State Bank Notes, 45
W. M. Hall.
ANNOUNCEMENT.
The following is a complete list of the papers read at
the monthly meetings of the Colorado College Scientific
Society during the past year. Three of the papers are
printed in full in this pamphlet, while others will be pub¬
lished elsewhere.
October 18,1892;
Folk Etymology in Latin, - - - W. P. Mustard.
November 18,1892:
A Construction for the Imaginary Points
and Branches of Plane Curves, - - F. H. Loud.
December 16, 1892:
State Bank Notes, W. M. Hall.
January 21, 1893:
Friction Tests in Water-pipes and Fire¬
hose, W. Strieby.
February 24, 1893:
Prayer in a Universe of Law, - - - E. S. Parsons.
March 24, 1893:
Acidimetry, D. J. Carnegie.
On the Eight Lines Usually Prefixed to
Horat. Serm. 1.10, - - - - W. P. Mustard.
April 28, 1893:
Kant's Theory of Space and Time, - - Marion McG. Noyes.
On the Multiplication of Semi-convergent
Series, Florian Cajori.
May 19,1893:
The Essential Element of Religion, - - F. R. Hastings.
Multipolar Dynamos, - - . . Florian Cajori.
The Circular Locus, - - - F. H. Loud.
THE CIRCULAR LOCUS
Geometrically Constructed to Show Imaginary Values of the
Variables.
By FRANK H. LOUD.
In the paper on "A Geometrical Construction for the
Imaginary Points and Branches of Plane Curves," which
I read before this society on November 18, 1892, the gen¬
eral method of construction therein outlined was illus¬
trated by the simple example of the equation Y''=r^;
and it was shown by a diagram how the full significance of
this equation, for imaginary as well as real values of the
variables, may be geometrically interpreted by the aid of
additional curves, accompanying the circle described
around the origin. A more full and methodical treatment
of the theory of this plan of construction, in its general
application, has since been contributed to the Annals of
Mathematics, but at the date of the present reading has
not appeared in print. It is the object of the present
paper to continue somewhat further the treatment of the
circular locus just mentioned, as a special case of the gen¬
eral theory, borrowing, from the two papers above named,
as much as may be necessary to render this intelligible to
a reader who has seen neither of the others.
The principle of construction employed is of course
based upon the well-known geometric interpretation of im-
aginaries, in which a+ia is represented by a line drawn
from the origin to a point a units to the right of a vertical
axis and a units above a horizontal axis, called the imagi¬
nary and the real axis respectively.
, The apparatus postulated in this usual representation
of imaginarie#—a pair of rectangular axes in a plane—
coincides precisely with that of the still more familiar
Cartesian method of translating algebraic equations into
6
Colorado College Studies.
geometric forms, upon whicli is reared the edifice of ana¬
lytical geometry. In the customary treatment of the latter,
while imaginary values of the variables appear frequently
in the algebraic work, and are recognized as of high im¬
portance to the theory of curves (witness the "circular
points at infinity"), they are excluded from geometric in¬
terpretation. This is not necessary. Imaginaries may be
admitted, with "real" quantities, into the constructions as
well as the arguments of analytical geometry, if we are
content to lay aside that habit of associating each axis
with a single variable, which has resulted in the names
"axis of X" and "axis of Y" respectively. Let us regard
these lines rather as an axis of reals and an axis of imagi¬
naries, and then express the usual Cartesian method of
locating a point by its coordinates, by saying that the point
(x, y) means the point at the extremity of the vector x-fty.
When x and y are real, this will locate the point just as
Descartes does, but if either coordinate be imaginary, the
point has still a definite position in the plane. Thus if
x=5—2i and y=4-f3f we findxd-fy=5—3=2-f-2f,
and the point is situated 2 units to the right of one axis,
and 2 above the other, just as if its coordinates were 2, 2.
Thus, when imaginaries are admitted, any point of a
plane serves for the geometric representation of an infinite
number of sets of coordinates, all distinct from one an¬
other, and we can no longer infer from the positiop alone
of a point what are its coordinates. If we are informed
by some other means what is the imaginary part of each
coordinate, then this knowledge, combined with that of the
position of the point, suffices to determine the real part,
and hence the coordinates in full. Thus in the instance
given, if we know that x-|-fy=2-|-2f, and that the imagi¬
nary part of x is — 2i, we find by subtraction that the im¬
aginary part of iY is 4f, hence that the real part of y is 4.
In like manner may be found the real part of x. ,
An equation between the variables, such as x^-fY''=j*^
serves to restrict the number of sets of coordinates belong¬
ing to any one point; never depriving any point, however.
The Circular Locus.
7
of its capacity of representing at least one such set. To
render visible this effect of the equation, it is necessary to
indicate, for points in different parts of the plane, by what
coordinates they may, consistently with the equation, be
represented; and this is effected, as already mentioned, by
indicating the imaginary part of each coordinate. If a
line is drawn through all these points of the plane for
which the imaginary part of x has a certain constant value,
say li, another through all those points for which its value
is 27, etc., then this system of lines will indicate to the eye
the value of the imaginary part of x for all points of
the plane. Another series of lines will indicate in the
same way the manner in which the imaginary part of y
varies over the plane; and when these two things are known
for any point, the real parts of the coordinates become also
known, and the geometric significance of the equation is
fully set forth. It is true that unless a point be situated
exactly on one of the lines of each series, its coordinates
are only approximately indicated; but, as will be seen, it
will always be possible to draw a line of each set through
any assigned point of the plane, and ascertain the value of
the coefficient of i which remains constant upon that line;
thus the determination of the coordinates may be made
precise.
To these lines I have ventured to give the name of
comitants, designating the two series as £c-comitants and
i/-comitants respectively, and affixing to either name the
number or symbol denoting the constant value of the co¬
efficient of i in the expression for the coordinate of any
point upon it. Thus the ic-comitant is defined to mean
a line (or curve) drawn through every point for which the
imaginary part of the value of x has the value w-.
I will also adopt in the remainder of this paper, the
rule of denoting by small capitals a, b, etc., quantities
which are entirely unrestricted in value, and hence are, in
general, comply; while for their real parts I use italic let¬
ters, and Greek letters for the coefficients of the imaginary
8
CoLOEADO College Studies.
unit. Thus A=a+i«, b=6+u?, etc. The Greek letter an¬
swering to c is taken to be y, and that answering to Y to
be t].
To return to the comitants, it is plain that one of each
series is of chief importance, namely, the comitant-zero.
This may be compared to the equator on a map, while the
comitant +1 and the comitant —-1 are on opposite sides like
parallels of latitude. The a:-comitant 0 passes through all
the points for which x is real, and the i/-comitant 0 through
all those for which ¥ is real, so that all "real points" of
the locus—that is, those having both coordinates real—
must lie on both these lines. For all real curves, there¬
fore, the comitants zero will have a common arc, and this
arc will be—or, at least, will include—the curve itself, as
known to the ordinary constructions of analytical geom¬
etry. Thus for the equation of our present example,
Y^=?'^ the a;-comitant 0 consists of the circle of radius r
described about the origin, and in addition of a line coin¬
ciding with the real axis. The ?/-comitant 0 consists of
the same circle with the addition of the axis of imagina-
ries.* The other comitants, of either series, are cubic
curves situated on opposite sides of the axis named, and
having oval branches within the circle, as will shortly be
seen.
A rule for constructing the comitants by points may be
derived by inspection of the equation. For the a:-comi-
tants, we may put the latter in the form when
we have, by extraction of the square root, and the addition
of X to each member,
x-f-n'=x=h-v/(x+?-) (x—r).
The mean proportional between x+r and x—r, which,
as the radical indicates, is to be found, is to be understood
of course not merely as having the length implied, in the
Euclidean use of the word, but as bisecting the angle at
♦Beside having the circle in common, these two comitants zero intersect
also at the origin, for this point of the locus may be regarded as having either of
its co-ordinates real, but since the latter cannot both be real at once, the origin
is not included in the real part of the locus.
The Circular Locus.
9
the origin formed by the two vectors x+r and x—r. Simi¬
larly, the principle of vector-addition is to be borne in
mind in uniting the result with the term x. The ordinary
geometric constructions of a bisectrix and a mean propor¬
tional may be combined with a fair degree of convenience
as follows: Let the two axes, OJ and 01,
ink, or so as to remain perman&tly through the construc¬
tion. If the ic-comitant m is to be drawn, where ij. is a given
quantity, let a point M be taken on the axis of imaginaries,
at a distance ij- above the origin; also a point S midway
between O and M; and let lines MN and ST be drawn par¬
allel to the real axis to an indefinite length. These two
lines will remain during the construction of a single comi-
tant, but all that follow must be erased and drawn anew
for each point constructed. On MN take any point X,
and on the same line two points, H and K, at distances
equal to r, on opposite sides of X. Of these, let H be on
the side of X opposite M. Draw OH. With center O and
radius OK describe an arc intersecting OH at G, and at G
erect a perpendicular to OH. From center U (the point
where OH meets ST) with radius UH, describe an arc cut¬
ting this perpendicular at Q. From K and G, with equal
10 CoLOEADO College Studies.
radii of any convenient length, describe arcs meeting at F;
draw OF, and on it take OL and OL' in opposite direc¬
tions, each equal to OQ.* On the side of LOL' toward X,
describe arcs from centers L and L', with radius OX; and
intersect each of them by an arc drawn from center X with
radius OL. Then P and P', the points of intersection, will
be points on the comitant curve, one on the infinite branch,
the other on the oval. Two more points on the same comi¬
tant are situated symmetrically to these, on the opposite
side of the imaginary axis. Also, the aj-comitant —u- is
equal to the a;-comitantand the real axis is an axis of
symmetry to the two curves. Further, if either of them
be rotated through a right angle, a ?/-comitant is produced;
but it must be noted that while, for all positive values of
//, the infinite branch of the aj-comitant is situated above
the real axis, that of the ?/-comitant //■ is to the left of the
axis of imaginaries. Thus a single construction virtually
determines sixteen points—four on each of two aj-comi-
tants and as many more on two i/-comitants.
Each comitant, •excepting the comitants zero, proves
when drawn to consist of a conchoidal and an oval branch,
the former approaching at infinity a line drawn parallel to
an axis (the real axis in the case of as-comitants) and at a
distance therefrom equal to double the coefficient (a) of i,
which distinguishes the particular comitant; while the oval
lies on the opposite side of this axis, touching the latter at
the origin. The breadth of each branch, in a direction
perpendicular to the above-named axis, is the same, and
is easily found to be V—//; while is the
greatest ordinate of the curve, belonging to the point where
the conchoidal branch cuts the other axis, which divides
it symmetrically. Kegarding together all the comitants of
one series, it is apparent that all have a common point at
♦Another method of finding a geometric mean between two lines which ex¬
tend from a common point is as follows; First, bisect the angle of the lines and
also its adjacent supplementary angle. On the latter bisectrix lay off half the
longer line, and from its extremity, in both directions, half the shorter, thus
obtaining the half sum and half difference of the lines. From the extremity of
the half-difference, with radius equal to the half sum, cut off on the bisectrix of
the angle a segment, which will be the required mean proportional.
The Cieculab Locus.
11
infinity, also all the ovals are mutually tangent at the
origin. Beginning with a very small value of //-, the corre¬
sponding comitant of course lies near the comitant zero,
which consists of a circle and a line; and it is seen that
the conchoidal part of the comitant answers to one semi-
circumference and to that part of the line which is outside
the circle, and lies just outside these parts of the comitant
zero. The oval, on the other hand, answers to the other
half the circumference and to its diameter, and lies inside
the semicircle close against the boundary. Accordingly,
its curvature is rapid on the side remote from the origin,
while near the latter it is almost straight. The succeeding
comitants have their conchoidal parts successively further
and further from the axis, each encompassing its predeces¬
sor, and more nearly straight than it, while the ovals lie
each one within the preceding, and are rounder as well as
smaller. Hence for !j.— cc, the comitant should consist of
a point (the origin), and a line at an infinite distance.
We are thus able to construct and describe the systems
of comitants from the equation x''-f-Y^==r^ alone; but if
we wish to determine the order of these curves, so as to
study them in the light of related forms, it becomes de¬
sirable to pass to new equations. In the article already
mentioned, contributed to the Annals of Mathematics, it is
shown that from the equation of any locus we may derive
that of another, whose real part shall coincide with any
specified comitant curve of the given locus. In the present
instance we shall obtain, for the general a;-comitant—the
aj-comitant f—the following result:
x'u+if—r'ij—2^ (x''+if)=Q-,
and for the ?/-comitant
x^+xif—r''x+2rj {x''+f)=0.
These may be called the "equations of the comitants," for
the sake of brevity of expression, if it be borne in mind
that from our ptesent point of view the only equation
which truly represents the comitants and jiothing more, is
12
Colorado College Studies.
that which at the same time represents them all, viz., the
equation x"+Y''=r^
The new equations show that all the comitants are
cubics; and the existence, as previously ascertained, of an
oval branch in each, at once refers them to that one of the
genera of Cayley and Salmon which consists of the projec¬
tions of the "parabola cum ovalV If a more minute
identification is desired, a transformation of coordinates,
easily effected, throws either equation into the standard
form discussed by Sir Isaac Newton in his "Enumeratio
Linearum Tertii Ordinisy The curves thus prove to be of
the kind described by him as "defective hyperbolas having
a diameter," and to belong to the species numbered 40,
whose distinguishing mark is the presence of the oval on
the concave side of the conchoidal branch. To write either
equation in the form adopted by Plticker as a standard,
no change of axes is necessary, but the equation of the
£c-comitants, for instance, becomes by a purely algebraic
modification,
In this expression, the existence of the asymptote
(?/—2?=0) and of the "asymptotic point" becomes
manifest, as also the position of the "satellite line" whose
equation is Among the diametral de¬
fective hyperbolas—or, to use language better correspond¬
ing to the vocabulary of Plticker, among cubics whose single
asymptote is osculating — the group numbered xxxiv is
distinguished by the fact that that line passes through the
asymptotic point, while the next preceding group, xxxiii,
differs from all others in which the asymptote and asymp¬
totic point are separate, by the fact that the satellite line
does not cut the curve. In the special case in which S has
V
the value —, the comitant belongs to xxxiv, otherwise to
xxxiii. In either case, the existence and position of the
The Circular Locus. 13
oval determine the species, in the classification of Plticker
V
as in that of Newton; so that if c=—, the curve is of
4
species 152, but, for other values of v, of species 148.
The equations of the comitants also suggest a process
of geometrical construction entirely different from that
deduced from the original equation of the locus. (See Fig.
let the axes and the circle of radius r and center O be again
drawn, and, in addition, a semicircle having for its diameter
that radius, 00, of the former circle which extends along the
imaginary axis in the direction indicated by the sign of
Draw also, through B, one of the points in which the circle
of radius r meets the real axis, a tangent to this circle.
All the foregoing may remain unerased during the entire
construction. On the tangent last drawn, take points Gl¬
and H, so that BG=/j'- and BH=2/i. Draw OGr, and pro¬
duce it sufficiently, so that a distance equal to GB may be
laid off from G on the produced part, to E, while the same
distance from G toward O, fixes the point D. Then OE
will be the maximum distance of the conchoidal branch
and OD that of tlie oval branch, from the axis of reals, and
the extremities of these maximum ordinates are to be
located on the other axis, in opposite directions from the
14
CoLOKADO College' Studies.
origin. In finding other points, the construction must
proceed somewhat differently for the two branches. For
the infinite branch, take on the line BG a distance BK
greater than BH and less than OE. Draw BC and OK,
and call their point of intersection F. Draw HF, inter¬
secting the imaginary axis at L, and then draw LM paral¬
lel to the real axis and meeting the semi-circumference.
the circle of radius r at N. Draw NQ, parallel to MC,
meeting the imaginary axis at Q. Finally, describe about
O, with radius OQ, an arc meeting at P and P' a parallel
to the real axis drawn through K. Then P and P' are
points of the conchoidal branch.
For the oval, extend the tangent GB on the opposite
side of the axis of reals, and take BK' in that direction, of
any length not exceeding CD. Draw OK' and CH, to in¬
tersect at F', and then F' B, meeting the imaginary axis
at S. Through S, a parallel to the real axis is to be drawn,
meeting the semi-circumference at T. Then an arc, with
radius OT, described about O, will meet the parallel to the
real axis drawn through K',in points belonging ^to the
oval.
If a parallel ruler is used in drawing, this construction
may prove more convenient than the preceding, since the
compasses will have to be adjusted only once in locating
each pair of new points. It should be mentioned that after
the distances OD and OE have been determined, we may,
if convenience require, replace the points B, G, H, K, K',
on a tangent to the circle, by points at equal heights on
any other parallel to the imaginary axis.
In each of the foregoing constructions for a comitant fi
it has been assumed that the value of /j. is directly given.
An important modification of the problem may be stated
as follows: Through any given point of the plane to
draw the comitants of a circular locus of given radius,
whose center is at the origin. Here it is necessary to de¬
termine at the outset the quantity (coefficient of i) which
of radius —
2
Draw OM, and produce it to meet
The Circular Locus.
15
characterizes each of the required comitants, and for this
purpose the comitant equations may be employed. Thus,
in the case of an a;-comitant, the equation may be written
-if 2 ) ® formula which directly suggests the
X +y
following geometric process: Draw by the usual methods
the polar of the given point with respect to the circle of
radius r, and from the point in which this polar meets the
line joining the given point to the origin draw a parallel
to the real axis, then the perpendicular distance from this
line to the given point is equal in absolute magnitude to
double the quantity f, answering to the /.i of the preceding
constructions. Having found this quantity, the comitant
is constructed as before.
It is to be observed that when f ancji are found by this
process, the coordinates of the given point are fully known,
hence this construction solves also the problem: To deter¬
mine geometrically the coordinates of a given point of a
plane, when regarded as a point of a circular locus of given
radius, having the origin as center.
Having now sufficiently considered the form and posi¬
tion of the comitant curves which make up the circular
locus, the next step will be to examine the most important
properties of the locus as they are discussed in the elemen¬
tary analytical geometry, and observe what new light is
shed by the present construction upon the familiar pro¬
cesses and results.
"A right line," it is commonly said, intersects the circle
in two points, which may be real and discrete, coincident,
or imaginary. Just as the "circle," here used to mean the
geometric equivalent of the equation, is in the present in¬
terpretation replaced by a double system of curves, together
forming the circular locus, so the right line gives place to
a double system of lines. These intersect the comitants
of the circular locus in every part of the plane, but since
these indefinitely numerous intersections of the separate
comitants are not liable to be confused with the two special
points mentioned in the theorem, the word "intersect"
16
CoLOEADO College Studies.
may be retained, and the proposition will read, "A circular
and a linear locus intersect at two points." By a point of
intersection of two loci must of course be meant one whose
coordinates, when it is regarded as a point of the one locus,
are the same as when it is taken to belong to the other.
If such a point, then, lies on the a:-comitant ? of one locus,
it is on the a;-comitant f of the other (the ? having the
same value for the two), and a similar statement is true of
the other system of comitants. Thus a point of intersec¬
tion of two loci may be defined as a poini in which hvo
comHants {viz., one of each series) belonging to one locus
are met by the corresponding comitants of the other locus.
The theorem of analytical geometry, above quoted, speci¬
fies not only the number of intersections of the two loci,
but their kinds. This, however, is done under the tacit
assumption that both loci are real. The full statement
intended, therefore, is as follows: "A circular and a linear
locus, each of which has a real branch, intersect at two
points, which may be real and discrete, real and coincident,
or conjugate imaginary." The locus of a linear equation
with real coefficients (called, for brevity, a real linear locus)
has the two comitants zero coinciding in a single right
line, while each of the series of comitants consists of
lines parallel to this. Real intersections, whether in dis¬
crete or consecutive points, are formed by the real parts
of the two loci, just as in the ordinary constructions of
analytical geometry. The situation of the imaginary inter¬
sections may be easily studied by combining the two equa¬
tions x^-bY'=r''' and x cos <p-\-Y sin <p=p, while assuming
p>r. Elimination gives x=p cos <p±i sin f^/p'—r^ and
\—p sin <p^i cos <p^p'—r'^, whence
x-t-zY=(p±v'p'''—r^) (cos <p + i sin <p).
It is at once apparent that the two intersections lie
on the perpendicular drawn from the origin to the real
part of the linear locus, at equal distances on opposite
sides of the latter, but always on the same side of
the origin. The intersection nearest the origin is within
the real part of the circular locus, since p—^p^—r''<r.
The Circular Locus.
17
hence the branches of its comitants which are here met by
the corresponding linear comitants are both ovals, while at
the other intersection of the loci, the conchoidal branches
alone are present. If p is made indefinitely great, the
latter intersection recedes to infinity, while the former
approaches the origin as its limiting position. In this
way is indicated the geometric representation of the " cir¬
cular points at infinity," only one of which, it appears, is
situated at an infinite distance on the plane, and this one
must be regarded as in an indeterminate direction from
the finite points of the locus. But the further examination
of these important points may be deferred a little until the
subject of the asymptotes is reached.
The geometric construction of the finite imaginary
points in which the circular locus may be intersected
by a real linear locus needs little further statement. The
real parts of the loci—the circle and non-secant line—are
supposed given. A perpendicular is to be drawn to the
line from the center of the circle (the origin), and from its
foot a tangent to the circumference. The length of this
tangent, laid off on the above-mentioned perpendicular in
both directions from its intersection with the given line,
marks out the points required.
By the aid of the circle may also be solved a problem,
which may often be required, viz; To draw other comitants
of a real linear locus, when the comitants zero {i. e., the
real line) are given. The distance between two comitants
of one system, say the a:-comitant /j- and the oj-comitant v,
for a given difference between a and v, depends on the
direction of the real line, and is independent of the latter's
distance from the origin. Hence if the given line happens
to be a secant, a parallel may be drawn to it which will lie
outside the circumference, and then the points of intersec¬
tion of the loci found as above. Selecting one of these
points—for instance, the exterior one—its distance from
the given line pyroves to be to the coefficients of i in its co¬
ordinates x and y, as unity to sin ^ and —cos f respectively.
The corresponding distance of the two comitants ij- will be
to /J. in the same ratio, hence these distances are ^ cosec <p
and —[I sec <p.
18
Colorado College Studies.
The rule that imaginary intersections of a circular and
a linear locus must be conjugate, and hence discrete, ceases
of course to apply if the linear locus is imaginary, when
two imaginary intersections may be coincident. In this
case, at the point of contact of the two loci an a"-comitant
of one must be touched by the corresponding a;-comitant
of the other, and also a i/-comitant of the first by its cor¬
responding ?/-comitant of the second, the two curves hav¬
ing in general different directions at the point, since in an
imaginary linear locus the two series of comitants need
not be parallel to each other. Two such linear loci, having
a real point Q in common, may touch the circular locus.
The usual form of this statement, that "two imaginary
tangents to a circle may be drawn through any point within
the latter," must not be allowed to give the impression
that the comitants of the linear loci, which are the actual
tangents, will pass through the point Q. This would of
course be impossible, since Q, as the sole real point of each
linear locus, is at the intersection of its comitants zero.
In fact, since the polar of Q with its comitants constitutes
a real linear locus, intersecting the circular locus in the
points of contact, the latter points must, as already shown,
be on the perpendicular from the origin on this polar; that
is, on the line OQ.
The complete geometric construction, exhibiting the
" tangents to a circle from a point within," may be made
as follows: (See figure, page 19).
The circle drawn around the origin as center, and the
point Q (which, to avoid undue simplification, may be
assumed to be on neither axis) are the only data needed.
The polar of Q is first to be drawn, and the intersections
made by the locus to which it belongs are to be found in
the manner just stated. These are the points of contact.
By a previous construction the coordinates of T, one of
these points, may be determined geometrically, and it
will be well (in order to render apparent the significance
of the subsequent construction) to sketch at the same
time the circular comitants which pass through T. Now
if the algebraic expressions for the coordinates of T be
The Circular Locus.
19
it is seen that, for the point of the tangent at which x=0,
y will be —. Accordingly, that point may be located by
n
finding (in direction as well as in magnitude) a third pro¬
portional to the quantities n and r. For this purpose, if
the vector ON expresses the quantity n, while OR is that
radius of the circle which coincides with the real axis, an
angle ROH must be made equal to NOR, and an angle
ORH equal to ONR, when the distance OH, cut off by the
bounding line of one of these angles on that of the otiier,
will represent the value of y. If OK make a positive angle
of 90° with OH, and be made equal to OH in length, it
will represent lY and hence x+fy; so that K is the point
of the tangent locus for which x=0. But this point must
be on the cc-comitant zero, and that line is accordingly QK.
A parallel to QK through T is the linear a?-comitant at
that point, aniwill be found to touch the a;-comitant of
the circular locus. Similarly, by first finding the point of
the tangent locus for which y=0, the tangent ^/-comitant
may be constructed; and in like manner both the comi-
20
Colorado College Studies.
tants of the other tangent locus may be drawn through T',
the second point of contact.
By a slight modification of this construction, a tangent
may be drawn at a given imaginary point of the locus.
For if T be given, the points of the tangent locus for which
x and y respectively vanish may be found as before, but Q
must be determined in order to obtain the directions of
the comitants zero. From the relations already stated it
is easily shown algebraically that if OT be a given dis¬
tance d, then OQ is found from the proportion
d''+r^: r^=2d : OQ;
which admits of ready geometric construction.*
Again, the construction of the polar of an imaginary
point whose coordinates are given is obtained in a similar
manner. For the equation of the polar of a point M, N is
in the same form MX-hNY=?'^ already used for the tangent,
hence the points of the required locus for which x and y
are severally zero are found as before, but the real point
must be separately determined. For this purpose we may
put for m and n respectively their expanded values m+iiJ-,
n-\-iv (where m, n, a and v are given real quantities), and
then if we assume that x and y are the real quantities x
and y, we can separate the equation (ra-t-t/i) x-\-{n+iv)y—
r''=0 into two (since the sums of the real and imaginary
terms must separately vanish), which will be mx+ny—r'=0
and ijx+vy=0. The real point of the locus is then at the
intersection of two lines, whereof the former is the polar
of a known point m, n; and the latter is a line through the
origin, the tangent of whose inclination to the real axis is
fJi
—With the determination of this point, two points of
each of the comitants zero become known, and hence these
lines may be drawn. To fully construct the locus, how¬
ever, it is needful to have the coordinates of one imaginary
point, that the distance between successive comitants
♦In this is included the solution of a problem relating to a comitant curve
considered as a variety of the cubic, and independently of its connection "with
the other comitants forming the locus; viz: To draw a tangent at a given point
of the curve.
The Cieculak Locus.
21
of eacli series may be known. Following the analogy
of the previous part of the problem, we may inquire
for the point, both of whose coordinates are pure im-
aginaries. Writing for x and i-q for y, the equation
becomes —r'^=Q and is resolved into
——vq—r^=0 and m^-\-nq=Q. Now the point whose
coordinates are if and iq is the same as that wliose
real coordinates are x= —q, y=^; hence the foregoing
resolved equation may be interpreted as directing to
a point at the intersection of two lines, one of which
is the polar of the known point v, —/x, and the other is
drawn through the origin at an inclination to the real axis
whose tangent is—. The perpendicular distance of the
point thus found from the real axis is in the same ratio to
its distance from the a:-comitant 0 as the unit of linear
measure is to the distance between the x-comitants 0 and 1;
and a similar proportion gives the interval between suc¬
cessive 2/-comitants.
Since every linear equation (unless its absolute term is
zero) may be thrown into the form MX-t-NY=r^, by multi¬
plying it through by the (real or imaginary) ratio of r® to
this absolute term, we have in the foregoing a direction
for constructing all the comitants of any such linear locus
given by its equation. The coefficients M and N, found in
this way, are the coordinates of the pole of the given locus.
The problem of finding the points of contact of the two
linear tangent loci which have a given imaginary point in
common is equivalent to that of finding the points of in¬
tersection of the circular locus by the polar of the given
point; and this may be done as follows, without the labor
of constructing the polar locus. The method is based on
an inspection of the result of a solution of the two equa¬
tions X^-|-Y''=r^ and MX-l7NY=rl It is found algebraically
^
that x-|-iY= nM. To express this re-
M—
suit geometrically, we have first to find a mean
proportional between M-|-iN and m—zn; then^v^r^—m''—n'',
22 CoLOEADo College Studies.
a mean proportional between r+v^and m^+n^
and finally a fourth proportional to M—iN, r, and
rzt-v/ r^—NI
If P is the given point, whose coordinates are M, N, and
if M is the point M, 0, then MP is equal to iN, and by pro¬
ducing PM to Q, making MQ=PM, the point M, —N, is
found. Hence the first step is accomplished when a dis¬
tance equal in magnitude to a mean proportional between
OP and OQ is laid off both ways from O on the line bisect¬
ing the angle POQ. From each of the points thus fixed a
distance r is then to be measured to the right, parallel to
the real axis, so fixing the points H, K. Now the angle
HOK is to be treated as was POQ; i. e., on its bisector is
to be laid off in each direction from O a length equal to a
mean proportional between its sides, and from each of the
points so found a distance r measured to the right, to the
points E and F respectively. If E be the right-hand ex¬
tremity of that diameter of the circle which lies on the
real axis, we have next to make a triangle OET similar to
OQR, on the base OE homologous to OQ (and with the
angle TOE equal in sense as well as in magnitude to EOQ),
and T will be one of the required points of contact; the
other having the same relation to OF that T has to OE.
(Figure omitted.)
The remark has been already made that any linear
locus which does not contain the point 0, 0, may be re¬
garded as represented by the equation MX-f NY=r^; hence
the foregoing construction of the intersections of such loci
needs only to be supplemented by discussing those of the
locus CY=sx, to complete the treatment of linear intersec¬
tions. Let the points C and S be the extremities of vectors
extending from O and having the values c and s respec¬
tively, and let P be the point whose (imaginary) coordi¬
nates are c, s. Produce PC to Q making CQ=PC, then the
vectors OP, OQ are o-his and c—is i-espectively; so that
OL and OL' (denoted by ±l) will represent dbv^o'^-l-s^
if L and L' be taken on the bisector of the angle POQ and
at distances each way from O equal to the mean propor¬
tional between the lengths OP, OQ. The coordinate x of
The Cieoulae Locus.
23
the point of intersection is now to be found as a third pro¬
portional to ±l, 0 and r (that is, the triangle ROX is to
be made similar to LOO), and similarly y is a third pro¬
portional to l, s and e. (Figure omitted.) The quantity
x-|-iy might, of course, be found at once, as in previous
cases; but the construction of the separate coordinates
may be more useful.*
It has now been shown how to find the intersection of
the circular locus by any linear locus whatever; a brief
mention should be made, however, of another mode of
attacking this problem, which may be best presented by
considering first the simpler one, to find the point of inter¬
section of two given linear loci. Suppose that, in each,
the two constants zero are given in position, also in each,
the a:-comitant ? (the ^ having the same value in one as in
the other), and in each, the ?/-comitant y). Join the inter¬
section of the a3-comitants 0 to that of the a;-comitants ?.
Now, since in either locus the distances from the oj-comi-
tant 0 to any two aj-comitants, ? and are as the numbers
f and f, it follows that the line just drawn will pass
through the intersections of any two like £c-comitants of
the two loci. So also the line joining the intersection of
the two ?/-comitants 0 with that of the ly-comitants will
pass through the intersections of all pairs of like ?/-comi-
tants. The point in which these two lines meet is obvi¬
ously the required point of intersection of the given linear
loci.
The points of intersection of any two algebraic loci
whatever may be determined by an application of the
same principle; that is, the curves which pass respec¬
tively through the intersections of like aj-comitants, and
through those of like ?/-comitants are always algebraic
curves, whose equations result from the elimination of f
or of Tj from a pair of comitant equations; and their real
intersections must always correspond in position with the
(real or imagftiary) intersections of the two given loci.
But the application of this method to determine the inter-
*The discussion of the intersections made with a circular locus by imaginary
radii leads directly to the theory of the trigonometric functions of an imaginary
variable, but this subject is much too extensive to be here entered upon.
24
CoLOEADO College Studies.
sections of the circular and linear locus is not practically
appropriate, since it invokes the aid of higher curves to
treat a problem which is in fact amenable to the ruler and
compasses. A similar objection must hold in other cases.
The problems thus far considered embrace the con¬
struction of linear loci as secants, tangents, or polars, when
imaginary quantities enter the problem in any way what¬
ever; and are hence adaptable to the treatment of any
specific elementary question which involves only one circle.
But there is one particular case of tangents which, on ac¬
count of its importance as well as of the special peculiari¬
ties it exhibits, requires a separate investigation. This
case is that of the asymptotes.
The equations of the asymptotes of the lo6us x''-|-Y^=7'^
Y . . Y . .
are x-|-iY=0, or—=i, andx—tY=0,or—=—i. It is at once
X ' ' X
apparent that the equation x-t-iY=0 for any (finite) values
of X and ycan be satisfied only at the origin; though from the
Y . .
form—=1, it appears that infinite values of x and Y might
differ numerically by any finite amount. Hence the finite
comitants of the locus all pass through the origin, while any
line whatever of the plane may be taken as a comitant in¬
finity. Now a real "line at infinity" is characterized by
opposite properties, i. e., its comitants ij., when ij. is any
finite quantity, lie altogether in the infinitely distant region
of the plane, unless the comitant zero be regarded as
parallel to an axis, when any other parallel to the same,
though at a finite distance therefrom, becomes a finite
comitant. But by assuming ij. infinite we may identify its
comitants with any lines in the finite region, irrespective of
direction. Hence the first "circular point at infinity" re¬
garded as the intersection of these two loci, is at any finite
point; and the statement that all circles pass through this
one "circular point," is only in this sense true, that one
analytical expression will serve to designate for all circles
the infinite coordinates which will satisfy their equations;
while, as the geometric equivalent of this analytical ex¬
pression is indeterminate, the point in question is in fact
geometrically different for different circles. It is, actually,
The Cieoulab Locus.
25
in each circle, situated at the center. Accordingly, in ex¬
amining the intersection of x cos ?>+¥ sin <p—p with the
locus, no indeterminateness was found to attach to the
position of the interior point of intersection, when p was
increased indefinitely; on the contrary, the limiting posi¬
tion of the intersection was found to be the center of the
circle. Through this point every comitant passes, and
each is there touched by the corresponding comitant of
the asymptote; while this point of contact, in the case of
a given comitant—say the a;-comitant —has for its coor¬
dinates x=cc -f-iAt, Y=ix. It is to be observed that although
in this way each single comitant exhibits the position of
the point at infinity, the entire series of comitants can
illustrate only one form of infinite value which might be
assigned to the variable x. For beside the value cc-f-tV,
where u- is finite, x might have the infinite value (x{x-\-k)
with a finite ratio between x and ?, or indeed it might be
x+icc, where x, the real part, is finite. But in these cases
the point of contact would fall on a comitant infinity.
This remai'k applies with still greater significance to the
consideration of the second asymptote, x—iy=0. This
locus has nothing of the unique quality which makes the
former asymptote a correlative to the line infinity. Its
a:-comitant 0 lies on the real axis and its i/-comitant 0 on
the imaginary axis, while any comitant ii- is at a distance
2,« from the comitant zero. On the a;-comitant <)■ the point
whose coordinate x has the value oc-f-z// is at an infinite
distance from the origin; and similarly for the z/-comitants.
So long, then, as ij- is finite, the point of intersection with
the line infinity is represented by the two points infinitely
distant on the two axes. Accordingly, every (finite) comi¬
tant of the circular locus has for its individual asymptote
the corresponding comitant of the locus x—z y=cr But the
second circular point at infinity must not on this ground
be asserted to be represented only by the infinitely dis¬
tant points of the axes, for if we take into account the
comitants infinity, the direction of the point in which the
asymptote locus meets the line infinity becomes indetermi¬
nate; and this agrees with the fact that the exterior inter-
26
Colorado College Studies.
section of the line x cos sin v=p, whenp was made
infinite, was found to be infinitely distant on the radius
bounding the angle <p.
Thus the circular points at infinity are not definitely
localized, but it is to be noted that their indeterminate-
ness results, not from their imaginary quality alone, nor
yet wholly from the infinity of their coordinates, but from
the combination of both characters, and the absence of
any means of imposing a definite value upon the ratio of
the real and imaginary parts.
The problems which have been discussed in the present
paper are mostly of the class which relate to properties
of the locus considered as a whole, rather than to those
of individual comitants. As such* problems when analyzed
will, as a rule, resolve themselves into investigations of the
intersections of the locus by other loci, they will generally
be distinguished by the mark that the comitants of the
two series enter similarly into the geometrical construc¬
tions; thus at the intersection of two loci the like aj-comi-
tants and also the like ^/-comitants meet in the same point.
Of the other class of investigations mentioned, viz., that in
which the properties of individual comitants are the subject
of inquiry, an instance occurs in obtaining the " comitant
equations." In such problems it is frequently necessary to
employ separate symbols for the real and imaginary parts
of constants or of variables; and if in the subsequent
course of the investigation, a symbol which has thus been
taken to represent a real quantity occurs as the representa¬
tive of the unknown quantity in an equation, imaginary
roots of such an equation must of necessity be treated as
impossible, since they contradict the hypothesis of reality.
This is just as if m, having been put to represent the in¬
tegral part of a mixed number, in some algebraic problem,
should afterward be determined by a quadratic equation,
one of whose roots should prove to be integral, the other
fractional. The latter root would of course be disregarded,
without the imputation of any unreal quality as belonging
to fractions.
The Circular Locus.
27
To illustrate by an example this class of inquiries, sup¬
pose that we desire to determine at what point a line, tan¬
gent to one of the comitants, cuts the same comitant again.
Let the a;-comitant // be the cnrve in question, then we
know that its tangent at the point M, N {i. e., the point
m+ifi, n+iv, when these quantities satisfy the equation
M®-|-N'=r), is the a:-comitant u- of the locus MX-fNY=rl
But the point at which these two lines again intersect will
not have the same coordinates, regarded as a point of the
linear locus, which it has as a point of the circular locus.
It is easily shown that a coincidence in position of points
on two like aj-comitants belonging to different loci, without
a concurrent intersection of the y-comitants, implies only
that the real parts of thd coordinates x for the coinciding
points differ by the same amount as the coefficients of i in the
imaginary parts of their coordinates y. If we represent
this unknown difference by d, we have the three equations
and
{x+iu+d) {m+iu) -1- {y+i-Q-i-id) {n+iv)=r^
from which to find x, y, and -q, eliminating d. Since each
of the equations can be resolved into two, by separating
the real and imaginary terms, we can eliminate also two of
the constants, as m and v, and find y in terms of r, u, and n.
Two values of y will of course be found equal to n, and
represent the coincident intersections at the point of con¬
tact, but the third, which is the subject of the inquiry, is
determined by the linear equation
From this value of y, that of x and q can be found, and the
tangential point is completely determined. As the equa¬
tion is linear, no trouble arises from imaginaries.
But let it be now required to find on the a:-comitant u
a point of inflection, using for the purpose the property
that at such a point the above-determined tangential point
must coincide with the point of contact. Then n is to be
substituted for y in the above equation, and the whole
28
CoLOBADO College Studies.
solved for n. One root, n=/«, can be immediately found,
and this will be seen to indicate the existence of a point of
inflection at an infinite distance. After dividing out the
factor 11—/J; there remains the biquadratic
Two of the roots of this equation are imaginary, and with
them a third must be rejected on the ground that it cannot
consist with real values of m and v. The remaining root
shows the position of the two real, finite, points of inflec¬
tion. The three rejected roots are just suflBcient in num¬
ber to represent the six imaginary inflections of the cubic
curve, whose real part coincides with the aj-comitant ,u;
but it seems plain that, consistently with the fundamental
notions of the present scheme of interpretation, it can
only be said that the latter curve, considered as a comitant
of the locus X'-f Y■=r^ does not possess these six inflec¬
tions.
As all of the foregoing discussion has been limited to
the interpretation of the equation x^+Y^=r^, the circular
locus which has been treated is not the most general one
to which the name applies, but is merely the real circular
locus having its center at the origin. It seems proper in
a closing paragraph or two, to indicate what modifications
of the foregoing constructions would result from their ex¬
tension to the circular locus in general.
The removal of the center from the origin is effected
by a parallel transformation of coordinates, in respect
to which it is only necessary to remark that transformation
to a real point simply changes the relative position of the
axes in respect to the entire system of curves, leaving the
latter unaffected, while transformation to an imaginary
point disturbs, not the form of the comitant curves, but
the numbers by which they are characterized, thus the
comitant zero may become the comitant fi, while some
other comitant of the same series becomes the new comi¬
tant zero. From this statement, the effect of such a change
on the foregoing geometrical constructions may be easily
estimated.
The Circular Locus.
29
A more important modification results from admitting
imaginary values of the radius. The equation x''+y^=r''
(when R=r+iV), is at once seen to belong to a singly in¬
finite series of different loci, which vary in form with the
magnitude of the ratio p : r. The case already considered
is that in which this ratio is zero; and the most closely
analogous case, as may be readily conjectured, is that in
which the ratio is infinite. These two cases alone can be
represented by equations with real coefficients.
The comitants of the locus x''+y®-|-/)''=0, like those of
x'-j-Y-=r^, belonging to Newton's "defective hyperbolas
having a diameter," being symmetrically divided by one
of the axes. The a:-comitant 0 is a straight line, co¬
inciding with the real axis, and the successive comitants ?,
when ? is small, are conchoidal curves, convex toward this
axis, and all touching it at the origin. Each lies within
its predecessor, and exhibits a greater curvature, until the
a;-comitant p is reached, when the curve, whose shape at
first might suggest a bowl, and later a purse with a narrow¬
ing neck, has at length completely closed together, and has
a node on the imaginary axis, at a height of p above the
origin. The succeeding comitants have ovals, like the comi¬
tants of the locus x^+Y^=r^, but these lie on the same
side of the real axis as the conchoidal branches, and op¬
posite the convexity instead of the concavity of the latter.
All the ovals, as in the former case, touch the real axis at
the origin. Thus it is seen that in a single series of comi¬
tants occur successively representatives of Newton's species
45, 41, and 39—the conchoidal hyperbola pura, nodata,
and cum ovali, the last having the oval on the convex side.
As f increases beyond p to infinity, the conchoidal branch
grows more straight, and the oval shrinks to a point at the
origin.
Between this form and that of the locus x''+Y^=r^ there
is an unbroken gradation, corresponding to the positive
values of the ratio p :• r; and similarly another for the nega¬
tive values. In the intermediate forms, however, the comi¬
tants are no longer symmetrical in respect to either axis.
30
CoLOBADO College Studies.
and mustlje classed among Newton's "defective hyperbolas
not having a diameter." The "comitant equations" are
x''y + >j''—2S{x^+ij-)+2rp.x+{p-—i'')y=0,
x^+xy-+2rj (x''+y'} + {p'—r^)x—2rp.y=0-,
(and from these as general forms the special cases already
considered are derived by making p or r equal to zero.)
All the comitants of a series pass through the origin, and
have there a common tangent. This tangent, however, for
the aj-series, is no longer the real axis, but has a slope of
21* p
— i' so that in the loci in which p=±r, the common
r"— p'
tangent coincides with the imaginary axis. The infinite
branches of the comitants are not conchoidal, but serpen¬
tine, crossing their asymptote (which is still parallel to
the real axis, and at a distance 2? therefrom) at a point
distant by ———— from the imaginary axis. In the case
of the comitant zero, this crossing is at the origin, and the
serpentine curve is symmetrical to that point as a center,
thus belonging to the Newtonian species numbered 38. But
as ? increases from the value 0, the successive comitants, no
longer possessing any kind of symmetry, belong at first to
the species 37, as they have no oval and no singularity.
There is, however, the same gradual closing into the form
of a narrow-necked purse, already observed in the case
r=0, and the comitant p is again nodate, so belonging to
the 34th species. For still greater values of f, the curve is(
of species 33, having an oval, which, as in all cases, shrinks
to a point at the origin as ? becomes infinite, the serpentine
branch in the meantime straightening toward coincidence
with its asymptote. The node on the a:-comitant p is at
that point of the locus for which y=0; and it may be re¬
marked, as true of all forms of the locus, that the four
points characterized by zero values of one or the other co¬
ordinate are double points of the comitants of opposite
name on which they fall.
Very slight and obvious modifications are alone required >
to adapt the first method given in the present paper for the
construction of comitants, to use with any given values of
r and p.
ON THE EIGHT LINES USUALLY PREFIXED TO
HORAT. SERM. I. 10/
By WILFEED P. MUSTAED.
The eight lines usually prefixed to Horace, Satires,
I. 10 are found only in some of the mss. of Keller and
Holder's third class. They are unknown to the mss. of
classes I and II, and to z and the whole Btt family of
class III. They were apparently unknown to the Scholiasts,
who would surely have considered them obscure enough
to require some explanation. Mavortius did not know
them. In Fl' and some other mss. they appear as the be¬
ginning of satire 10, while in /S/^np they form a continua¬
tion of satire 9.
On this external evidence almost all the editors have
condemned the lines as an interpolation, and either
marked them off by brackets or omitted them altogether.^
They appear as part of the text in Zarotto's Milan edition,
in the first and second Aldine editions, and in the Paris
edition by R. Stephanus. But even in the fifteenth cen¬
tury Landino rejected them, and most of the older editors
followed his example. Some editors have separated them
from the text but prefixed them to the satire, others have
printed them separately in their commentaries, while
many have omitted them altogether. Thus they do not
appear in ten of the Venice editions (for the omission in
the first eight Landino was responsible), in Bentley's,Wake-
field's and some twenty others. Lambin ascribes them to
some ' semidoctus nebulo' who wished to explain the open-
^ This paper offers no new theory as to the meaning, authorship or date of
these obscure lines. It is%ierely an attempt to collect and arrange the various
opinions that have been expressed with regard to them.
21 owe the greater part of the facts presented in this and the following para¬
graph to Kirchner's edition of the first book of the Satires (Leipzig, 1854), p. 142.
32
CoLOEADo College Studies.
ing word 'nempe.' Jacobus Cruquius barely mentions
them in his commentary as the words of a 'simius Hora-
tianus.' Bentley omits them without mention.
Others have defended the lines. Gesner restored them.
Valart thought they were the work of Horace. Heindorf,
followed by Bothe and others, thought that Horace had
written them as an introduction to this satire but after¬
wards threw them aside and commenced in a different
tone; or that they were an unfinished introduction to some
satire discovered after his death and, with the addition of
the expletive words 'ut redeam illuc,' prefixed to Sat. I.
10, on account of the similarity of subject. Jo; Val.
Francke proposed to insert them after verse 51 of this
satire, Reisig after verse 71. Morgenstern held that Horace
had written the lines, but afterwards rejected them.
Schmid' virtually said that they were the work of Horace.
Apitz^ ascribed them to Horace, but bracketed verse 8.
Urlichs® said that the old question is really one of sub¬
jective feeling as to what is worthy or unworthy of Horace.
He thought the lines genuine, though he admitted their
obscurity and considered the text corrupt. Doderlein
found nothing seriously objectionable in the lines, and
was quite certain of their genuineness. He maintained
that the fact that they are not found in many mss.
does not prove them spurious; this might be the result
of chance, or even of a recension by Horace himself.
W. Teuffel's® verdict was similar to Morgenstern's.
The text of these obscure lines is very corrupt. The
mss. of most importance for determining the original
reading are FA'/?'. F, the principal representative of the
large third class, is the assumed common source of the
^ gemelU Parisini,' <p 7974 and 4> 7971; A' the archetype of
a similar pair, I Leidensis and 1 Parisinusj /S' that of
/? Bernensis and f Franckeranus (now Leeuwardensts).
^Philol. XI. pp. 54-59.
^Coniectan. in Q. H. F, Satiras (Berlin, 1856), p. 86.
^ Rkein. Mns. XI. p. 602.
^Rhein. Mus. XXX. p. 621.
Horat. Serm. I. 10 (1-8).
33
These mss. agree very closely, and establish the text as
follows:
Lucili, quam sis mendosus, teste Catone
defensors tuo pervincam, qui male factos
emendare parat versus, hoc lenius ille
quo melior vir est, longe subtilior illo
qui multum puer et loris et funibus udis
exoratus, ut esset opem qui ferre poetis
antiquis posset contra fastidia nostra,
grammaticorum equitum doctissimus. ut redeam illuc,
" How full of faults you are, Lucilius, I shall clearly
prove from the testimony of Cato, your champion, who is
preparing to revise your ill made verses. He will deal
more gently with them inasmuch as he is a better man, of
far finer tastes, than the scholar who in his boyhood felt
the vigorous persuasion of moistened thong and rope, in
order that there might be one who could lend a helping
hand to the poets of old against the carping criticism of
our day, the cleverest of aristocratic grammarians. To re¬
turn to that point,"
notes on the text.
Vs.l. ^quod sis' {codd.plerique ap. Lamb.). Some of
the abbreviated forms of 'quam' and 'quod' in minuscular
writing are very much alike.' Unless very carefully written
these words might be readily confused, and so 'quod' may
have appeared here. When once it had appeared in a ms.
it might easily be retained because of its use in late Latin
to introduce substantival clauses after 'verba dicendi et
sentiendi.®
Vs. 2. 'convincam' {edfLandini ex mss.) for 'pervin¬
cam,' which as the more difficult reading should be re¬
tained. One ms. {Kirchneri cod. L in Dresd. III.) gives
'devincam.' Peerlkamp suggested 'prope vincam.'
Fs. 4. 'quo melior vir est.' This is the reading of the
most important mss. The false quantity in 'vir' has
'Chassant, Dictionnaire des abreviations^ latines et francaises, Paris. 1876, p. 77.
sDraeger, Hist. Syntax der latein. Sprache^ Vol, xl, p. 229.
34
CoLOEADO College Studies.
given rise to many attempts at improving the line. Thus
one ms. has 'quo vir melior est,' another 'quo vir est
melior,' a third 'quo est vir melior,' while several read 'est
quo vir melior.' The last arrangement of the words gives
undue emphasis to 'est.' Lambin conjectured 'quo
melior is est,' and the Mariinius of Cruquius, the only
one of his mss. that contained these eight lines, had
'quo melior hie est.' But there are pronouns enough
already in 'ille . . . illo.' Several mss. had 'quo melior vir
et est longe subtilior.' Meineke defended this hyperbaton
for 'quo melior vir est et longe subtilior,' appealing to
Sat. I. 8, 68; I. 4, 68; I. 9, 51. This, however, gives the
impossible combination 'quo longe subtilior.' Heindorf
found 'adest' in Berol. 5 and accepted it.
Fs. 5. 'puer et.' The obscurity of this line has given
rise to several emendations: 'puer est' (Gesner); 'pueros'
(Urlichs); 'puerum est' (Reisig); 'nuper' (Rutgers);
'fuerit' (Praedicow, who also read 'quem' and 'exhorta-
tus'); 'pueros' (Nipperdey®). W. TeuffeP" suggested 'me
olim' for 'multum' and defended 'olim' by a reference to
Sat. I. 4, 105.
T's. 6. ' exoratus' is confirmed by the number and im¬
portance of the mss. in which it is found. The other
mss. readings 'exortatus' and 'exhortatus' are only pos¬
sible with ' puerum' in the preceding line, for there is very
little authority for the active form or passive meaning of
'exhortor.' In any case the omission of 'est' is a diffi¬
culty, and hence, apparently, Peerlkamp's conjecture 'est
hortatus.' The conjectures 'exornatus' (Glareanus) and
'est ornatus' (Valart) are obviously suggested by such ex¬
pressions as ' adeo exornatum dabo, adeo depexum, ut dum
vivat, meminerit mei.'" Horkel apparently wanted a good
strong word after 'loris et funibus,' and settled upon 'ex-
coriatus,' which Meineke and Schutz approve.
" Opusc. 493.
^"Bhein. Mus. XXX. p. 622.
" Ter. Heaut. 5,1, 77.
Hoe at. Seem. I. 10 (1-8).
35
Fss. 4-6. In the Rheimsches Museum fur Philologie,
XLI. pp. 552-556, F. Marx offered the following emen¬
dation: •
—hoc leniuB ille,
quo melior veisu est, longe eubtilior illo
qui multum puerum et loris et funibus ussit
exoratus,—
His explanation and defense of these changes are given
below.
COMHEENTAKY.
In the very first verse there is evidence of the spurious
nature of this fragment, for (1) the promise 'quam sis
mendosus, teste Catone, pervincam' is not fulfilled, and (2)
the sentiment is unlike Horace. In the tenth satire he
defends the opinion he had pronounced upon Lucilius in
Sat. I. 4, but with full recognition of his peculiar merits,
and elsewhere he very modestly claims for himself a lower
place than for his predecessor.'® "To Lucilius he pays also
the sincerer tribute of frequent imitation. He made him
his model, in regard both to form and substance, in his
satires; and even in his epistles he still acknowledges the
guidance of his earliest master." "
'Teste Catone.' The Cato here referred to is the gram¬
marian Valerius Cato, who is mentioned in Suetonius" as
'poetam simul grammaticumque notissimum,' 'summum
grammaticum optimum poetam,'' Cato grammaticus, latina
Siren.' Another section of Suetonius tells of Cato's in¬
terest in the works of Lucilius, 'quas (sc. Lucili saturas)
legisse se apud Archelaum Pompeius Lenaeus, apud Philo-
comum Valerius Cato praedicant.'"
Those who see in the person here compared with Cato
the 'plagosum Orbilium' of Horace, Epp. II. 1, 70, assume
that the writer of these lines knew that epistle, which is
12 Sat. II. 1, 29, *me pedibus delectat claudere verba, Lucili ritu, nostrum
melioris utroque.' Mid. 74, *quicquid sum ego, quamvis infra Lucili censum
ingeniumque.'
13 Seller, The Roman Poets of the Republic^ 3d ed., 1889, p. 249.
1^ Dc G^ramm. 4 and 11.
13 De Gramm. 2.
36
Colorado College Studies.
assigned by Vahlen to B. C. 14. Suetonius, de gramm. 11,
says of Cato, 'vixit ad extremam senectutem,' so that
' emendare parat' might be literally true if the lines were
genuine. Marx claims that the words need mean only
'emendare studet, emendationi operam dat, emendaturus
est,' comparing Juv. 8, 130, 'per oppida curvis unguibus
ire parat nummos raptura Calaeno.' Moreover, he main¬
tains, the author of these lines pronounces upon the whole
recension of Cato, implying that it was already finished, so
that they were not necessarily composed in the time of
Horace.
Keller objects even to the sentiment of 'teste Catone'
that (1) Horace required no one's authority to confirm his
opinion of Lucilius, and (2), in view of Epp. I. 19, 39-40,
it is not likely that he would have appealed to the author¬
ity of any grammarian.'® This he regards as another evi¬
dence of interpolation.
Fs. 3. Some editors punctuate with a period after
'versus,' and another after 'doctissimus,' verse 8. With
this punctuation 'hoc' would most naturally be taken as
accusative after a finite verb understood. It seems better
to point with commas and supply such a participle as
'facturus,' taking 'hoc' as the ablative corresponding to
'quo.'
Fs. 4 is certainly corrupt.
(a) It is strange that 'melior' should be given as a
reason for 'lenius.' It must have been this diflBculty that
gave rise to the variant 'lenior.' Cato's moral character is
not at all concerned. All that is required of him is ability
to correct metrical errors and halting sense in Lucilius'
verses, defects which had probably been multiplied even
in his day by mistakes of the copyists. Nor does 'sub-
tilior' suit 'lenius,' for Lucilius' verses are 'male facti.'
(h) There is a false quantity in 'vir.'"
'"'non ego, nobilium scrjptorum auditor et ultor,
grammaticas ambire tribus et pulpita dignor.'
. "The Italian dialects show that the 'i' in 'vir' was once long (eeir): cp.
Buecheler, Lex. Ital. p. 30.
Horat. Serm. 1.10 (1-8),
37
(c) ' Longe subtilior' is irregular. " Cicero and the older
writers did not use ' longe' to strengthen the comparative,
though it appears in poets of a later age and in the more
recent historians."" Wolflinn" says that Horace kept
strictly to the old rule of 'multo' with the comparative,
using 'longe' only in one anomalous case. He would
therefore not have written 'longe' here instead of its met¬
rical equivalent 'multo,' and its use is one proof of the
spurious nature of these eight lines.
(d) ' Hie' and ' illo,' ending consecutive lines and refer¬
ring to different persons, are strange and confusing as to
meaning. Suetonius rejected a certain prose epistle which
purported to have been written by Horace, 'epistula etiam
obscura, quo vitio minime tenebatur'.™ He would scarcely
have found the transparency of genuineness in verses 3-4.
To avoid the difficulties in 'lenius' and 'ille . . . illo' Schiitz
would strike out the two half-lines and read 'emendare
parat versus subtilior illo."
Vs. 5. If the genuineness of verse 4 may be questioned
on the ground of obscurity, still more objectionable is
verse 5. It seems impossible to explain this and the fol¬
lowing lines in their best attested form. For example,
who is the person compared with Cato?
(а) Because Horace says, Epp. II. 1, 70, that he studied
the poems of Livius Andronicus in his boyhood under the
' plagosus Orbilius,' many editors have made ' qui puer . . .
exoratus' refer to the poet himself. It may be doubted
whether Horace would have thus spoken of himself, but a
greater difficulty awaits us inverse 8, 'equitum doctissimus.'
These words most naturally refer to the same person as
'qui . . . exoratus,' and Horace was not an 'eques.'
(б) Eeisig, who reads 'puerum . . . exhortatus,' makes
'puerum' refer to Horace, 'qui' to Orbilius. But to this
Schtitz objects that 'puerum' would be too indefinite with¬
out ' istum' or iillum.'
i^Hand, Tursellinusy III. p. 551.
Comparationy p. 40.
^Horatii Poetae Vita.
38
CoiiOEADO College Studies.
Schmid" also read 'qui . . . puerum . . . exhortatus,' re¬
ferring ' qui' to Orbilius.
W. TeufifeP refers' puerum' to Scribonius Aphrodisius,
'qui' to Orbilius. To this also Schutz objects that Scri¬
bonius was 'Orbili servus atque discipulus,"® and that
'puerum' would not imply all this. He might more rea¬
sonably have repeated his objection to Eeisig's explanation,
that the unmodified 'puerum' is too indefinite.
These three interpretations are obviously based upon
the mention of the 'plagosus Orbilius,' Epp. II. 1, 70, and
they receive some support from the words ' grammaticorum
equitum doctissimus,' in verse 8. These words naturally
refer to the same person as the clause 'qui ... puerum ...
exhortatus,' and Orbilius might, at least ironically, be
called a knight." There is, however, no evidence that he
revised Lucilius' ' ill made verses,' or that he paid special
attention to them.
(c) J. Becker''® thought that either Florus or Titius is
meant. Very little is known of these men except from
Horace, Epp. I. 8, and II. 2. Horace merely says that
Florus has ability enough to win distinction in oratory,
in law, or in poetry.®' Porphyrio says 'hie Florus [scriba]
fuit satirarum scriptor, cuius sunt electae ex Ennio,
Lucilio, Varrone.' Kiessling hints that the old commen¬
tator inferred all this from Epp. I. 3, 21, 'quae circum-
volitas agilis thyma ?' Whether right or not, Porphyrio
apparently means that Florus rewrote some of the poems
of these earlier authors, adapting them for the readers of
his own day. Even if this be accepted, it is hard to s,up-
pose that Horace would refer to Florus in the language of
these eight lines, and yet address him fifteen years later
as a young man who had not written much," Of Titius
still less is known. Horace asks Florus whether he is still
^Philol. XI. pp. 54^59.
^Rhein. Mus. XXX p. 622.
^ Sueton. De Gramm. 19.
2*Sueton. De Gramm. 9, ' deinde in Macedonia comieulo, mox equo meruit.'
^Philol. IV. p. 490.
26 Epp. i. 3, 23-25.
« Epp. 1.3, 22-25.
Horat. Seem. I. 10 (1-8).
39
writing odes or trying his hand at tragedy, 'Titius Eomana
brevi venturus in ora.'^ All that the scholiasts have to say
about him may very well have been derived from the text.
Thus Becker's theory seems to have very little support,
except Porphyrio's statement that Florus was a writer of
satires, and the fact that Titius and Florus were both
noblemen of a literary turn, and might be called ' equitum
doctissimi.' That either of them could be called ' gram-
maticorum equitum doctissimus' is by no means apparent.
' Loris et funibus udis.' The mention of 'lora' and
'funes' suggests a rather savage treatment of the un¬
known youth referred to in this line. References to the
use of 'funes' for the purpose of punishment are not very
numerous. Horace, however, has ' Hibericis peruste funi-
bus latus,'® on which Orelli remarks that 'funes' made
from the Spanish broom were used for flogging the ma¬
rines. No very satisfactory explanation of the word 'udis'
has ever been offered. It is not clear that savage masters
sometimes used a moistened lash, or that a lash so treated
would cause the victim more pain. Marx'" quotes Petro-
nius, 134 B, 'lorum in aqua,' as inconsistent with such ex¬
planations. It is unfortunate that the wisdom of the
scholiasts was not brought to bear upon this word; their
comments would certainly have been interesting.
Fas. 3-6. The changes in these three lines suggested by
F. Marx have been mentioned on page 35. First he empha¬
sizes the importance of the word' exoratus' in the interpreta¬
tion of this fragment, a word which is preserved by all the
best mss. of the third class. This word, he says, may here
be equivalent to 'though vainly implored for mercy,' like
'exorata' in Juvenal, 6, 415, ' vicinos humiles rapere et con-
cidere loris exorata solet.'" Then reading 'puerum' for
'puer,"^ as many earlier scholars have done, he looks about
28Epp. I. 3,9.
^Epod. 4, 3. •
^Rhein. Mus. XLI. p. 552.
^ A similar use 'exorare,' which he might have quoted, is found in Hor.
Epp. 1.1,6, * latet abditus agro, ne populum extrema toties exoret harena.' With
this meaning of ' exoret,' ' toties ' may be taken literally.
An easy change paleographically.
40
Colorado College Studies.
for a finite verb of ' striking' or ' cutting.' This, he thinks,
is lurking in ' udis,' which is certainly very weak and has
never been well explained. The verb is probably ' ussit.'
It should be noticed that the word 'udis' appears'm ras. /?,'
and that very often in mss. the termination '-it' shows a
medial'd.' '^ For similar uses of the verb 'urere' cp. Horace,
Epp. I. 16, 47, 'loris non ureris'; Epod. 4, 3, 'Hibericis
peruste funibus'; Sat. II. 7, 58, 'virgis uri.' The conjec¬
ture 'quo melior versu est' in the fourth line he puts for¬
ward with less confidence.
Marx then refers his new reading, 'qui multum
puerum . . . ussit exoratus,' to Vettius Philocomus, Cato's
teacher, who was one of the first to revise the work of
Lucilius.^' This man, as being 'Lucilii familiaris,' and
possibly the same person who was censured by the poet
'propter sermonem parum urbanum,"® may have been like
Aelius Stilo and Servius Clodius, a Eoman knight. His
name, however, suggests a Greek origin, and in the absence
of any special statement as to his rank, it is not easy to
assume that he was an 'eques.'
T's. 8. The words 'grammaticorum equitum doctissi-
mus' are very difficult both in reference and in meaning.
They would most naturally refer to the same person as
'qui . . . exoratus,' but they can hardly apply to the per¬
son who is so unfavorably compared with Cato. Schiitz
claims that such irony as this is quite impossible here, and
failing to find any other person to whom the epithet could
easily be referred, would strike out the words altogether.
Apitz"" bracketed the whole of verse 8.
Kirchner and Doderlein would refer 'doctissimus' to
the same person as 'melior' and 'subtilior,' i. e., to Cato.
^Examples of this interchange in Horatian mss. are cited by Keller and
Holder, Epilegom. III. p. 8.53. A similar list is given in Mayor's The Latin Hepta¬
teuch, p. 251.
^Sueton. De Gramm. 2.
® Quint. Inst. Or. I. 5, 56, taceo de tuscis et sabinis et praenestinis quoque:
nam et eomm sermone utentem Vettium (Vectium?) Lucilius insectatur, quem-
admodum Pollio reprfihendit in Livio Patavinitatem, licet omnia italics pro
romanis habeam.
Coniectan. in Q. H. F. Satiras, 1856, p. 86.
Horat. Serm. I. 10 (1-8).
41
The long separation is decidedly against this, and, besides,
Cato could hardly be called an 'eques.' According to
Suetonius, De Gramm., 11, his social position was doubtful
in his manhood and he probably never had a knight's in¬
come in his old age. To meet this last difficulty Kirchner
proposed to read 'equidem' for 'equitum.'
The reading 'doctissime' has been proposed, but this
is obviously suggested by the knowledge that Lucilius
was a knight, and the objectionable interval is only in¬
creased.
The words 'grammaticorum equitum' are especially
obscure. As they stand they would seem to imply a class
of knights who were grammarians, or of grammarians who
were knights," but such guilds are quite unknown.
Doderlein punctuated with a comma after'grammati¬
corum.' As has been mentioned above, he considered
these eight verses the genuine introduction to Sat. I. 10,
so that in trying to avoid one difficulty he created another
almost as serious, by making Horace class himself among
the grammarians—'fastidia nostra grammaticorum."®
Badius Ascensis thought Maecenas was the 'eques';
another old scholar thought of Laberius. Orelli came to
the conclusion that the writer of these vei'ses, whoever he
was, knew no more who the 'eques' was than we do.
'Ut redeam illuc.' Cp. Sat. 1.1, 108, 'illuc, unde abii,
redeo,' and Nepos, Dion., A, 'sed illuc reverter'; Agesil. 4,
'sed illuc redeam us.'
It is hard to find anything in the preceding lines to
which 'illuc' can well be referred. As Kruger®* remarks, it
cannot refer to the promised proof that Lucilius is full of
faults, for this promise is not fulfilled, or to the proof of
his faults on Cato's evidence, for Horace does not return to
this at all. Voss and Francke made 'illuc' refer in a gen¬
eral way to Sat. I. 4, or its subject.
" Like Juvenal, ^11. 49, nobilis Indoctl,' a nobleman who is an ignoramus.'
^This is contrary to the sentiment of Epp. 1.19, 40,' non egro . . . grammati-
cas arabire trlbus at pulpita dignor.'
'^Drei Satiren fuer den Schulzweck erklaert, 1850, p. 17.
42
Colorado College Studies.
It seems almost certain that these three words were in¬
serted on account of the abrupt opening, 'Nempe etc.'"
The preceding lines were probably written with the text
of Sat. I. 10 on account of the similarity of subject, and
some later scribe, mistaking them for the introduction to
this satire, would add the words ' ut redeam illuc' to serve
as a bridge to the lively opening 'Nempe incomposito dixi
etc.,' though, as Schtitz remarks, they would serve better to
connect the verses with verse 2, 'quis tarn Lucili fautor
inepte est?' The long introduction to Sat. 1.7 (followed by
'ad Regem redeo,' vs. 9) may have suggested the expletive
words that were felt necessary. Keller and Holder cite as
similar interpolations the four lines once prefixed to the
Aeneid and the ten lines at the beginning of Hesiod's
Works and Days. It is incontestable, they add, that the
satire is complete without these eight verses, and that
nothing is wanting at the beginning. On the contrary,
the fact that Persius, the deliberate imitator of Horace,
begins one of his satires (the third) with 'nempe' speaks
for the genuineness of the introductory 'nempe' here.
The external evidence that these eight verses are an
interpolation to Sat. I. 10 is given in the first paragraph
of this paper; a-careful examination of them can only re¬
sult in the conclusion that they are not the work of Horace
at all. They have been assigned to different writers and
to different periods.
Kirchner ascribed them to Furius Bibaculus (circ. 700
A. U. C.), arguing from Sueton. De Oramm.ll, that Valerius
Cato, if still alive when Horace wrote this satire (A. U. C.
720), must haye been over seventy years old, too old to be
contemplating a revision of Lucilius. This argument was
soon afterwards disposed of by Schmid," who proved from
the same section of Suetonius that Cato could not have
been more than sixty-two years old in A. U. C. 720, and
^' Scil. ut transitus ad Horatium sit.' Baehrens, Fragm. Poet, Roman., 1886, p. 329.
XI. p. 54.
HOB AT. SEEM. I. 10 (1-8).
43
was probably alive several years later." C. Fr. Hermann
ascribed them to Fannius. Lucian Mtlller, in his edition
of Lucilius, 1872, says they were undoubtedly composed in
the time of Horace, though their authorship is uncertain.
These three scholars insisted on taking 'emendare parat'
literally.
Schtitz says that the writer of the fifth verse appar¬
ently knew not only Epod. 4, 8,' Hibericis peruste funibus'
and 4, 11, 'sectus flagellis . . . praeconis ad fastidium,' but
also Epp. II. 1, 70, 'plagosum . . . Orbilium, etc.' This
epistle is assigned by Vahlen to B. C. 14, so that these
verses could not have been written by Fannius or by
Furius Bibaculus. He would put the composition of the
fragment as late at least as the beginning of the second
century A. D. Just as Tacitus^' says that there are men
in his day who prefer Lucilius to Horace, and Quintilian"
insists that Horace's criticism is unfair, so the unknown
writer of these lines objects to Horace's treatment of his
own model, appealing to the authority of Cato, who was of
course not satisfied with the work of Lucilius as he found
it, but still thought it worth revising.*^ The third verse,
Schutz maintains, is not necessarily older than Sueton.
De Gramm. 2. The writer may have known Suetonius'
account of Cato and yet made him an editor not merely a
student of Cato in his younger days, either by mistake or
because he knew or thought he knew better.
Orelli remarks that the passage has ' antiquum colorem,'
and assigns it to the time of Fronto. Keller would put it
as late as Ausonius (circ. 850 A. D.), hinting at Tetra-
dius who is addressed in Anson. Ep. 15, 9, as rivalling
Lucilius.*®
F. Marx, whose beautiful emendation of these lines is
often referred to in this paper, says that they are impor¬
tant for the history of grammar at Rome and for our
*3* vixit ad extremam senectutem.'
^Dial. de Or at. 23>
Or. X. 1, 93.
^ It would be hard to show that Horace's estimate of Lucilius was any lower
than this.
rudes Camenas qui Suessae praevenis aevoque cedis, non stilo.'
44
Colorado College Studies.
knowledge of the fate of Lucilius' poems. The whole pass¬
age, he insists, suggests the philologist and reviewer, who
prefers Cato's edition of Lucilius to his master's earlier
one. There is a vast difference between the points of view
of Horace and the author of these interpolated lines; the
former speaks of Lucilius himself and his works, the latter
of editors and editions.
If it once be assumed that the words 'emendare parat'
do not necessarily imply that these lines were written in
Cato's lifetime, it is hard to say how late they may have
been composed. Whatever their age, it is quite impossible
to name their author.
The fragment—and it is only a flagment, for the promise
in the first verse is not fulfilled—seems to have been trans¬
ferred to this satire from some source rather than composed
as an introduction to it, to explain and complete it. Apart
from the fact that the general sentiment of the lines (so
far as this can be discovered) is not in accord with that of
the satire to which they are unnecessarily prefixed, it is
hard to see what Horace had to do with Cato's alleged re¬
vision of Lucilius or with the savage treatment of the un¬
fortunate youth referred to in verse 5. Keller and Holder
say that the 'Urhandschrift' of their third class of mss.
was older than Priscian, and so also this interpolation,
adding, however, that while Priscian quotes the spurious
lines prefixed to the Aeneid, these eight verses are not
mentioned by any of the ancient commentators.
STATE BANK NOTES.
By W. M. HABL.
The proposal to restore the privilege of note-circulation
to banks outside of the national bank system, by removing
the practically prohibitory ten per cent, tax, is supported
chiefly by the following doctrines:
I. That the probable extinction of the national bank
circulation will leave a gap in the money-supply that must
be filled by notes of some kind.
II. That a well-guarded system of state bank notes
would give us an "elastic" circulation, i. e., one that
would increase with each high tide of business, and con¬
tract when business slackened.
III. That state bank notes would give a larger perma¬
nent money-circulation to parts of the country that are
now scantily supplied with money.
IV. That the present prohibitory tax on state bank
notes violates the spirit of the Constitution if not its letter,
and is a dangerous encroachment upon State powers or
individual liberty or both.
I.—NOTES TO FILL A VACANCY.
The first of these doctrines could be summarily dis¬
missed, in view of the well-known habits of the interna¬
tional flow of gold, except so far as the shrinkage of the
whole money-supply of the world would affect the scale of
prices a little; a shrinkage that can be avoided by other
means than bank notes. Yet the recent experience of the
United States with money is not only an illustration of
the international flow, but it is worth examination because
it offers striking and encouraging proof that the substitu¬
tion of coin for national bank notes is not likely to be a
painful process.
46 Colorado College Studies.
From the monthly estimates made by the Treasury
Department are taken the following figures, showing the
amount of each kind of money in circulation on July 1 of
the year named. Money held by the banks is included,
for the stock they keep does not far exceed (though it does
in July somewhat exceed) a reasonable reserve, which is as
much a part of the needs of ordinary business as is the
reserve of five dollars or fifty below which the head of a
family does not permit his cash in hand to fall. Money in
the Treasury is not included, because much of it is held
merely to redeem certificates that are circulating outside;
and because there has been a widely varying amount there,
the variations of which had an unbusinesslike origin. There
would be no material difference in results, so far as the pur¬
pose of this paper is concerned, if the money in the Treas¬
ury, less the backing of certificates, were included. The
figures in parentheses for the true amount of national bank
notes are round numbers, estimated from the reports of the
Comptroller of the Currency; this needs to be distinguished
from the nominal amount, because notes of surrendered
circulation, being no longer an obligation upon the banks
that issued them, are really certificates payable by the
United States.
MONEY IN CIRCULATION.
(Millions of dollars.)
1879
1882
1885
1888
1890
1892
Gold* (including Gold Certificates)..
126
363
468
512
505
550
Silver Dollars (including Certificates)
9
87
141
256
360
384
Greenbacks and Legal Tender Certif.
302
325
331
308
335
342
Notes of 1890
98
National Bank Notes, nominally
321
352
309
245
182
167
(National Bank Notes, really)
(310)
(315)
(270)
(153)
(125)
(140)
Subsidiary Silver
67
52
44
50
54
62
Totals
825
1,179
1,293 .
1,371
1,436
1,603
[Copper and nickel coins are disregarded; so is paper fractional currency,
which was reckoned about 16 millions in 1879 and only about 7 millions since,
including the amount in the Treasury. The figures of subsidiary silver for 1879
and 1882 are too large, through including trade dollars.]
* The figures for gold, after 1879, are often disputed as too large; and prob¬
ably with good reason. But it will be seen (page 56) that allowance for a smaller
amount does not vitiate the conclusions of this paper.
State Bank Notes.
47
It may here be seen clearly how the whole volume of
money has responded to the needs of increased business;
the growth was rapid in the revival of business following
1879, and then fell to a much lower rate, averaging little
over 30 millions annually from 1882 to 1890. But the fact
which now most concerns us is that the needs of business
were not provided for by the creation of bank notes, nor
of any kind of notes, except the note-element in the silver
dollars and the notes of 1890, and a small increase in the
greenbacks outside of the Treasury. More than that, the
nominal bank-note circulation was reduced in the thirteen
years by 154 millions, and the true bank-note circulation
by about 170 millions. If 1882 and 1892 be compared, the
reduction in the ten years is 185 or 175 millions; a reduc¬
tion greater than the amount now outstanding. That is,
we have only to do once more just what we have done since
1882, and the whole of the national bank notes will be re¬
placed by other money.
But the matter is not quite so simple, because we shall
not do just what we have done since 1882. The effect of
the Act of 1890 needs to be considered, and the effect of a
possible repeal of that Act. Before weighing these, it is
desirable to look closely at the nature of the past additions
to the money-supply, in respect to their real cost. Their
cost to the country is measured approximately by the export
value which the gold and silver would have had if not used
for money purposes here. The cost of coinage and storage,
and other such minor corrections, may be disregarded, in
view of the wide allowance for error that will be used in
the inquiry, and of the unequivocal result. Of course the
government purchases have steadily "bulled" the silver
market; how much, it is not possible to know. Against
whatever such enhancement of the price of silver there
has been, acting as a diminution of the cost to the country
(not the government only) of the silver used for money,
there is a partial offset in the increase of cost to the country
of all its money-metal, through the necessity of making
slightly lower average prices for exported goods in order
48
Colorado College Studies.
to send them out in place of the metal withheld and thus
maintain the equilibrium of foreign trade. But to put the
result of the inquiry beyond suspicion, it may be prudent
to allow for the one conspicuous effect through enhance¬
ment of price of silver; and figures taken both with and
without that allowance will be limits between which the
truth lies.
Evidently we must include in the cost not only the im¬
ported metal, but the metal produced here, so far as either
has been used for money. And for this purpose we may
better allow for the Treasury holdings also, because if
there is an increase of metal there the country has bought
it by exporting goods or by abstaining from importing
them. The increase in gold used for money, either out¬
right or through certificates, represents one large part of
our expenditure to procure new money. The other large
part is represented by the gold-value for export* of the
silver in the added silver dollars, pZws the silver bought by
notes of 1890. The supply of silver dollars in the middle of
1879, including the Treasury stock, was 41 millions; in 1882,
123 millions; in 1892, 414 millions. In the figures for 1879
and 1882 are counted several millions of silver bullion,
destined soon to become dollars; the much larger amount
of silver bullion in 1892, and the much wider divergence
of its coinage-value and cost-price, are cause for consider¬
ing it separately below. The increase from 1879 to 1882
was 82 millions, which cost the government as bullion
about 72 millions; the international market value was a
little less, but we may neglect the error. The silver that
made the increase of 291 millions of silver dollars, 1882 to
1892, was substantially all bought by the middle of 1891;
it cost the government about 230 millions. Using this
purchase-cost as the upper limit of what the silver really
cost the country, we have yet to fix the lower limit sug¬
gested above. Higher price of silver, caused by govern¬
ment buying, affects for this purpose not only the silver
thus withheld from export, but the silver still exported.
* This is the export-value from time to time; not the present export-value of
the accumulated mass.
State Bank Notes.
49
The change of price in silver that would in any case have
been used at home does not sensibly affect the cost, being
a mere readjustment of domestic exchanges. The correc¬
tion applies, then, to the silver bought by government,
added to the net silver-export still remaining (which may
be a positive or negative quantity; the latter representing
an import and consequent loss by the raised price). The
net export of silver from 1879 to 1892 was worth about
$100,000,000; from 1882 to 1892, about $80,000,000. The
government purchases from 1879 to 1890 were about a
quarter of the world's product, and since 1890 more than
a third, and their effect on the price must have been con¬
siderable; but it seems liberal to set three-quarters of the
actual price as the lower limit of the price as it might have
been with no government purchases except for subsidiary
coinage. On that scale, the goods received in exchange for
the exported silver* of 1879-92 may, at the lower limit,
have cost the country $25,000,000 less than their apparent
cost; for the exported silver of 1882-92, $20,000,000 less.
Any such gain diminishes the cost of our use of silver for
money, and corresponding deductions are incorporated in
the following table, where the cost of the silver bought by
the Treasury appears separately, with the same three-
quarters rule used to deduce a lower limit of true cost.
COST TO THE COUNTRY, IN GOLD.
(Millions ot dollars.)
1879-92
1882-92
Lower
limit.
Upper
'limit.
Lower
limit.
Upper
limit.
226
302
172
58
—20
157
230
77
58
—25
418
77
418
157
677
52
797
61
367
37
464
46*4
Increase of Silver Dollars, 373 millions
Increase of Silver Dollars, 291 millions
Silver bought with 1890 notes, and not coined
Deduction for enhanced value of silver exported.
Increase of Goldf
Whole cost
Average cost per year.
»
* It would be a needless refinement of the question to take account of the
diminished home production and export, due to lower price.
t Including gold coin and bullion held by the Treasury. The official estimate
is 246 millions in 1879, 507 in 1882, 664 in 1892.
50 • CoLOEADO College Studies.
That is to say, the country has given full value in goods
and labor for somewhere between 677 and 797 millions of
its increase of money-supply since 1879; and for between
367 and 464 millions of the increase since 1882.
The money-supply itself, outside of the Treasury, in¬
creased by 778 millions from 1879 to 1892 (see table, p. 46);
but the decrease of national bank notes caused the increase
of the other elements of the currency to be still larger.
Gold increased 424 millions, silver dollars 375 millions,
"greenbacks" 40 millions, and 98 millions of 1890 notes
were added; making an increase, aside from national bank
notes and pieces less than one dollar (which last would
have shown about the same behavior under any system of
major currency), of 937 millions. This last is the amount
of money that has been added in thirteen years past to
meet the needs of increased business and take the place of
the declining bank note circulation. But we have seen
that the country earned meanwhile, i. e., bought with
goods and labor for which it received nothing else in
exchange, between 677 and 797 millions.* That is, the
note-elementf in the addition of 937 millions was between
140 and 260 millions. If 1882 and 1892 be compared, the
whole addition of money other than national bank notes
and small pieces will appear as 599 millions, and the note-
* This comparison of increase of money-supply outside the Treasury with
increase of money-metal both within and without the Treasury may seem irra¬
tional. But the former is the true measure of past additions to the money-supply
and the better basis for judging what future additions are probable, and hence
what the strain of making them will be; while the sacrifice in former acquisi¬
tions is better measured by the addition of metal in Treasury and outside circu¬
lation together. If any one nevertheless prefers to compare outside circulation
in both cases, he wUl find the increase of silver dollars (table, p. 46) from 1879 to
1892 to be 375 millions, 1890 notes 98 millions, gold 424 millions, and the resulting
" lower and upper limits " about 700 and 825 millions; difforipg from the 677 and
797 millions, reckoned above, in the direction of decreasing the note-element in
past acquisitions, and therefore of decreasing the sacrifice needed in future acqui¬
sitions that may contain a less note-element or none at all. That is, it would
strengthen the conclusion that in the text above is based upon a less favorable
supposition.
tNot the note-element reckoned upon the present bullion value of silver,
but the unearned part of the issues of silver dollars and 1890 notes as they were
made.
State Bank Notes.
51
element as between 135 and 282 millions. The following
figures show, accordingly, the average annual addition:
Whole addition. Note-element.
(Millions.)
Annually, 1879 to 1892 72 Between 11 and 20
Annually, 1882 to 1892 60 Between 1354 and 23
And the country has earned (see, also, the table on p. 49)
between 52 and 61 millions annually through the longer
period, and between 87 and 46^ millions annually through
the shorter.
It may safely be said that our probable dealing with
silver in the next few years (omitting free coinage as too
improbable in the immediate future to justify the discus¬
sion, necessarily long, of its bearing on the present ques¬
tion) will lie within a range bounded by—
(1) Continuance of the Act of 1890.
(2) Revival of the Act of 1878.
(8) Purchase of silver, and issue of notes whose
silver backing, reckoned as bullion, is kept equal to
the face value of the notes; kept equal by subsequent
purchase of silver, if necessary, without issue of
notes against the supplementary silver.
(4) Suspension of silver purchases, except for
small coins.
It is quite possible that silver legislation may combine
two of these methods, or change the amount of silver to
be bought under (1) or (2). But the present object is to
discover whether the national sacrifice in obtaining addi¬
tional money will be greater hereafter than it has been for
a few years past, and that object will be sufiiciently
attained by taking each method separately and noting the
effect in (1),'(2) and (8) of different amounts of silver-
purchase ; for any combination will be more favorable than
the least favorable method standing alone.
(1.) Continuance of the Act of 1890. If this happens,
the addition of money will be wholly earned, except for the
"lower limit" purpose a note-element due to the higher
price of the silver bought and the silver exported. The
52
Colorado College Studies.
silver bought is 54 million ounces annually, which is sub¬
stantially the whole amount available for Treasury pur¬
chase or export.* The domestic production of silver is
increasing by about 4 million ounces per year; but sup¬
posing (to keep on the less favorable side of probabilityf)
that the amount exported in the next dozen years should
average only 6 million ounces, while 54 millions were still
bought, the amount through which the higher price could
operate to diminish the true cost would be about 60
million ounces annually; worth $60,000,000 at one dollar,
$45,000,000 at 75 cents. Accordingly the note-element, on
the three-quarters scale, lies between zero and 15 millions
in the improbable event of a rise of silver that carried it
to average $1 an ounce, between zero and 11 millions if
silver averaged 75 cents. A smaller government purchase
would not change the quantity of silver affected, but it
would of course bring the note-element nearer to the zero
limit through affecting the price less.
(2.) Revival of the Act of 1878. Taking its minimum
purchase of $24,000,000 worth of silver annually, the dol¬
lars coined would be, with silver at $1 an ounce, 31 mil¬
lions; with silver at 75 cents, 41 millions. The seigniorage
would thus be 7 and 17 millions at those prices respectively.
The other part of the note-element, by the three-quarters
rule, would be (as under the Act of 1890) between zero and
15 millions at the former price, between zero and 11 mil¬
lions at the latter. The whole note-element is thus between
7 and 22 millions when silver is at one dollar an ounce,
between 17 and 28 millions at 75 cents. Evidently the
note-eleilient is enlarged by increased purchases or by a
fall of silver.
(B.) Issue of notes with a constantly equivalent silver
backing; a backing kept equivalent, when the price of silver
declines, by purchase of more silver without issue of notes
* The net import was about 3 millions in the fiscal year 1891; net export 6
millions in 1892.
t A larger supposed export would increase the note-element and decrease the
sacrifice.
State Bank Notes.
53
against it. The question, highly important for other pur¬
poses, whether the notes are redeemable in gold or in a gold
dollar's worth of silver, has no bearing on this discussion.
In either case the note-element is between zero and a quarter
of the export-price of 60 million ounces, minus the cost of
silver bought in case of falling price to keep up the backing
of notes issued earlier—that kind of purchase being cost
without addition to the money-supply. It would be an
extreme supposition that silver should fall to 60 cents an
ounce in the next ten years; that would be about 2^ cents
annually. Such a fall would require, if the annual pur¬
chase for note-issue were $24,000,000, a purchase of sup¬
plementary silver amounting to less than a million dollars
in the first year, to 10 millions in the last year, but averag¬
ing about 5 millions annually through the ten years; while
the note-element due to upholding the price of silver would
average (with silver at an average of 72 cents) between
zero and 11 millions. Deducting the 5 millions of cost for
supplements, we have minus 5 and plus 6 millions as the
limits of the note-element; that is, it might possibly be a
more expensive way of obtaining new money than import¬
ing- gold would be.* On the less extreme supposition of a
fall of silver to 70 cents in ten years, the average annual
supplementary purchase (the principal purchase being still
24 millions) would be something less than 3 millions, mak¬
ing the note-element somewhere between minus 3 and. plus
9 millions.f The increased expense, in the later years, of
maintaining such a note-system in case of a progressive
fall of silver is of course a serious objection to the system,
unless it is believed that silver will not continue to fall.
If silver does not change in price, the note-element is the
same as under the Act of 1890; with silver at 84 cents, it
is between zero and 12| millions. Greater purchases would
*A loss of this kind, payable in future, has already been incurred by the
country through its large purchase of silver, if silvjer does not rise again, and if
the notes of 1890 or lilver dollars are ever given a 100 per cent, backing or are
withdrawn and the silver sold.
t Silver then averages about 77 cents, and the note-element, aside from cost
of supplements, is between zero and IVA millions.
54
Colorado College Studies.
probably increase the note-element unless silver declined
2 cents or more yearly.
(4.) Suspension of silver purchases, except for small
coins. This would leave the natural movement of gold to
make the necessary increase of money, and would provide
no note-element.
Tabulating the effects of these methods of dealing with
silver, we have the note-element appearing as follows:
Method (1) ,with Act of '90 unchanged;
silver at 100
Method (1), with Act of '90 unchanged;
silver at 75
Method (2), with annual purchase
$24,(^,000; silver at 100
Method (2), with annual purchase
$24,000,000; sUver at 75
Method (3), with annual purchase
(for note issue) $24,000,000; silver
declining 2H cents yearly
Method (3), with purchase 24 mill.;
silver declining 1)4 cents
Method (3), with purchase 24 mill.;
no decline of silver
Method (4)
NOTE-ELEMENT LIES
EFFECT UPON THE
BETWEEN—
NOTE-ELEMENT—
of increased
of cheaper
and
15
mill.)
purchases.
silver.
0
[
Increase.
Decrease.
0
and
11
mill. ^
7
and
22
mill.)
(
Increase.
Increase.
17
and
28
mill.)
-5
and
+6
mill.*
Uncertain.
Decrease.
-3
and
+9
mill.*
Uncertain.
Decrease.
0
and
12)4
mill.
Increase.
Decrease.
No note-element.
The past annual increase of the whole money-supply,
together with the money that replaced bank notes, has in¬
cluded a note-element lying somewhere between 11 and 23
millions (see page 51). If we continue to extinguish bank
notes at the same rate, make no change in the amount of
greenbacks, and increase the whole money-supply at the
same rate as before, it appears from the table above that
Method (2) would involve no appreciable decrease, per¬
haps an increase, in the note-element; that is, the money
to serve the growing needs of trade and to take the place
of disappearing notes would cost us not appreciably more,
perhaps less, than it has in the recent past. Under Method
(1) the national expense on this score would be say 8 to 12
millions more, annually, than it has been in the recent past.
*For ten years only, and as an average; the note-element being less than
zero in the later years, and going further below after the ten years, if the faU of
silver continued at anything like the same rate.
State Bank Notes.
55
Under Method (4) it would be between 10 and 20 millions
more. Under Method (3) it might in a very unfavorable
case be 20 millions more, but with a slower decline of
silver the added expense would be nearer the 12 millions or
so (between 10 and 15) which would accompany a stationary
price of silver. Under Method (8) this average cost through
ten years represents a smaller cost in the earlier years and
a heavier one in the later years, if silver falls. It is only
under Method (8) that we have to anticipate a cost, for
the average annual addition of money and extinction of
bank notes, exceeding by more than about 15 millions the
cost that has already become habitual. Method (8), if
silver should fall rapidly, would be burdensome after a few
years, particularly if the annual issue of notes were much
more than the 24 millions reckoned in the table; but no
one wishes to see that method adopted if silver is to fall
rapidly; and in any case, the extinction of bank notes
within a dozen years would contribute only 12 or 14 mil¬
lions annually to the burden. Under any of the more prob¬
able forms of dealing with silver the sacrifice of the country,
in extinguishing the bank notes while it increased the
whole circulation as usual, would not exceed by more than
about 15 millions the sacrifice that is already customary;
and it might not exceed that at all. Remembering that in
place of an annual cost of between 40 and 60 millions for
the near future, which has been the implied basis of the
present reckoning because it was the average cost for the
past few years (see page 49), we might have for a part of
the time, as in 1879-82, a cost of 100 millions attended by
great commercial prosperity—remembering, too, that it
takes more than an occasional waste of 20 or 80 millions
by Congress to make an appreciable difference in the course
of business—it seems unlikely that the withdrawal of all
the national bank notes within ten years can give a sensi¬
ble check to business. Indeed, the greatest expense for
new money comes just at the time when the country can
best afford it, in times of rapid growth of business; and
just at the time when there is need of a check upon excessive
speculation.
56
Colorado College Studies.
The conclusion just reached has so wide a margin of
safety that it excuses the omission, for simplicity's sake, of
a number of corrections; some offset each other, some are
mere differences of degree of an element common to all the
years {e.g. a deduction from the probably excessive Treasury
estimate of gold coin in private hands), and the aggregate
of the corrections can scarcely swell the difference between
past and future sacrifice in the enlargement of the money-
supply so as to call for the retention of national bank
notes, or for the provision of any other notes to take their
place. If there is any need for state bank notes, it is to be
found elsewhere.
ii.—elasticity.
In popular discussion of the repeal of the bank-note
tax it is often assumed, as something near an axiom, that
a bank note system may readily be made " elastic," and it
seems to be implied that the easier it is for banks to issue
notes the more elastic the resulting currency will be. But
amon^ economists this is so far from being a generally
accepted truth that some reputable writers deny the pos¬
sibility of bank notes following the needs of trade, either in
expansion or contraction (except in the same way that coin
would have done), so long as the bank notes are really
convertible, i. e. are promptly and willingly redeemed by
the bank. If nevertheless we grant that an expansion is
possible, it is reckless to assume, without careful examina¬
tion, that the bank-note currency would contract again when
trade slackened. And unless it does so contract, what we
have is not elasticity but a wholly inelastic distensibility.
Entering first a protest against another too easy assump¬
tion, that elasticity is an unmixed good (for much may be
said for the doctrine that the evil in it exceeds the good,
through removing one of the barriers against speculative
excitement), we have to inquire what are the causes that
may limit a note-circulation,and whether any action of the
State governments upon those causes can give an increase
State Bank Notes.
57
or an elasticity that the National government cannot give
by similar action.
A bank issues notes in order to increase its receipts of
interest. In a country where notes are familiar, it can
usually carry notes with a reserve smaller than that which
it needs to carry deposits*; and accordingly, unless taxes'
or other expenses intervene, its loans that can be made
through notes are more profitable than its loans through
book-credits of deposit. But in the United States most
borrowers prefer book-credits, and the practicable note-
issue is restricted to so much as can be paid out, whether
in loans or in other money-payments (e.ff.npon checks pre¬
sented), without coming back for redemption faster than
it is reissued. Within that limit (beyond it, if bank notes
were not convertible) the bank has a motive for keeping
its circulation as large as possible, unless other expenses
or hindrances appear. In the United States the limit so
set would be narrow for the individual bank, on account
of the large proportion of credit-transactions, except for
the habitually long life of the circulating notes; in fact it
is so wide that a limit for the whole note-circulation, drawn
on the same scale, would be impossibly large. The real
limit for the whole note-circulation is of course much lower,
because as the whole amount approached a point consid¬
ered to be dangerous, redemptions would become more fre¬
quent, i. e. the limit for individual banks would shrink.
Banks do not grow weary of making a profit, nor stop issu¬
ing notes without a reason for stopping. Where the note-
circulation falls short of the limit (usually wide, when
banks are well managed) set by the return of notes for re¬
demption, it is certain that there are definite causes for it,
either prohibiting the increase of circulation or offsetting
the profit by some expense, inconvenience or dread of in¬
jury. Including redemption, we may name the following
restraints upon the issue of notes, some of which are
»
* Strictly speaking, deposits which are caused directly or indirectly by the
bank's loans. Other deposits have no bearing on the question whether loans by
book-credit or by notes are more profitable.
58
Colorado College Studies.
found at work in every bank-note system, no matter how
bad:
checks upon the issue of bank notes.
1. Return of notes for redemption. The effect of this
important restraint has been outlined above. It is thor¬
oughly effectual only when redemption is enforced by law
and not discouraged by public opinion or by bank pressure
(e. g. refusing discounts and other bank services to persons
who have presented notes for redemption). But as we shall
see hereafter, unless certain artificial means are used to
compel the return of the notes within a given time, the
action of this check does not prevent an increase from year
to year till the issue is very large, if public confidence in
the soundness of the banks prevails.
2. Fear of discredit. That is, a belief of the bank
managers that further issue of its notes would impair the
bank's credit, and either directly fail of its purpose by
bringing back for redemption notes equal to the new issue,
or injure the deposits and other business of the bank.
3. Fear of general injury to business. This may in¬
clude one or more of the following elements: Fear of the
effect on the bank's own business of a general derangement
of business caused by bad currency; fear of the effect of
such derangement on the interests of the managers outside
the bank; and a sense of responsibility and trusteeship
towards the business community. This check is seen at
its best where a single large bank issues most of the bank
notes of a country (the circulation of notes of other banks
being prevented or kept within narrow limits bylaw); the
Bank of England, for instance, would doubtless be tem¬
perate in the issue of notes, even if it were not hindered
by law from making any profit by an increase of circula¬
tion. The Bank of France is influenced by a similar com¬
bined responsibility and prudence. But when there are
many banks, each knows that its own note-issue will be
only a small part of the whole note-circulation, and that
its own abstention from new issues will have little effect
State Bank Notes.
59
towards reducing the whole; perhaps no effect at all, be¬
cause other banks will issue more instead before the more
rapid return for redemption comes into play, or the legal
maximum, if any, is reached. And if some banks are still
conservative when the motive to be so is thus diminished,
other banks will surely, in such a country as the United
States, be more tempted by the profit than deterred by the
possible future evil, which is made scarcely more probable
by their venture; unless, indeed, the number and character
of the banks be so limited by law that a joint agreement is
practicable (a case which will be mentioned below). The
point is, that we cannot look to this check, unless supple¬
mented by an agreement among the banks, to prevent an im¬
mediate increase of bank circulation if the latter were made
otherwise profitable; for some banks would surely grasp
at the profit.
4. Legal limitation of the number of note-issuing banks,
either by requiring a sp'ecial legislative charter for each,
or by imposing onerous conditions for going into business
under general law. This check acts upon a part of the
field only, of course; leaving the banks which come within
the privilege free to increase circulation, except so far as
other checks interfere.
5. A legal maximum of bank note circulation. This,
if set low enough, is perfect insurance against an undesir¬
able enlargement. Evidently,however, it allows no "elas¬
ticity " beyond the maximum, and does nothing to prevent
the circulation rising to near the maximum, so that further
elasticity is impossible unless that begins by decrease;
and the decrease must then be due to other checks, and
not to this, unless the maximum itself is made different for
different times of year.
6. A legal minimum of reserve or of securities. So
far as this minimum is greater than the amount of reserve
or of securities which the banks would hold of their own
accord, it is a check upon circulation by reducing the profit.
In our national banks it takes the form of an amount of
60
Colorado College Studies.
bonds costing much more than the reserve that the banks
would voluntarily hold, with only partial compensation for
the difference in the low interest received on the bonds.
7. Taxes on circulation; another mode of reducing the
profit. Under the present national bank law, not only
does the tax on the notes of outside banks extinguish the
profit and prevent their issue, but the tax upon national
banks of one per cent, on circulation contributes materially
to the well-known unprofitableness to many of them of their
notes.
8. Legal requirements hampering the ready circula¬
tion of notes. For instance, that they shall be of large
denominations only, that they shall bear interest (this
cuts into the profit also), or that they shall be of cumbrous
size. Requirements that they should be indorsed on pass¬
ing, that they should be on some easily damaged kind of
paper, that they should be presented for redemption within
a certain time or lose part of their face value, would have
similar effect.
9. Agreement among banks to set limits similar to 5, 6
and 8. In view of the number of American banks and the
difficulty of making and enforcing such an agreement, it
would be a waste of time to discuss this as a possible check
upon future issues here; at least till it is seriously proposed
to have a few large banks monopolize the bank-note issue.
Depreciation may in times of inconvertibility act as a
check upon issue, but no one now proposes to have a sys¬
tem subject to enough depreciation to come within the
range of that check. Another check, now practically out
of the field, probably acted upon the bank-note circulation
in America early in the century: scarcity of capital and
high rewards for its use in other ways than banking. Some
men who might have been attracted by the high returns of
bank-note issue were still more attracted by other enter¬
prises that would employ their time so fully as to make
inconvenient the attempt to conduct a bank.
Turning back now to see what are the checks that keep
our national bank note circulation comparatively small.
State Bank Notes.
61
we observe at once that the checks numbered 2, 3, 5 and 9
have no effect upon it. There is no fear by any bank that
its credit would suffer by issuing notes up to the amount
permitted by law in view of its capital, no fear of general
injury to business by the issue of another hundred millions
or two*, no legal maximum of circulation, no agreement
among the banks. Under No. 8 the omission to make the
notes a general legal tender does not in practice restrict
their circulation, nor would the banks issue any more notes
if they were still permitted to use denominations less than
five dollars; the exclusion of bank notes from the legal
reserve of national banks acts towards encouraging the
return of the notes for redemption, thus setting at work
check No. 1. Contrariwise, the law has by its assimilation
of bank notes to government notes, in size and general
aspect, done a little towards promoting their ready circula-
. tion. No. 4, legal limitation of the tiumber of note-issuing
banks, appears in the form of "onerous conditions," such
as a minimum of capital, government inspection, prohibi¬
tion of real-estate loans and of all loans beyond a certain
multiple of the reserve held; but this is more than off¬
set, on the whole, by the advantage which national banks
receive in public opinion of their probable soundness,
and it would not prevent an increase of note-circulation
if such circulation offei-ed a profit. We have left, therefore,
the checks numbered 1, 6 and 7; deducting No. 1, which is
not a limit but a drag upon increase (making it slower
without stopping it), the true causes of the smallness of
the circulation are in Nos. 6 and 7, i. e., (a) the require¬
ment of deposit of bonds whose market value is much
higher than the amount of notes issued against them,
bonds which bear a lower interest than the bank's ordi¬
nary business yields and most of which depreciate (through
the effect of the approach of maturity upon their premium)
* Provided it were gradual, and the annual purchases of silver by the Treasury
were small. If brought face to face with the possibility of a large increase of
bank notes not so guarded, hanks would doubtless recognize the danger; but,
as suggested under No. 3 above, only a part of the banks would probably hold
back from issue.
62
CoLOEADO College Studies.
before the bank can sell them, (b) the small deposit of cash
for redemption purposes at Washington, (c) the one per
cent, tax on the average note-circulation of the bank.*
From many banks these take more than the whole profit
of the notes, and the banks tolerate the loss as a sort of
advertising expense, in order to keep the advantage of
being known to be under government inspection. The
decline of the note-circulation before 1890 shows that on
the average the loss exceeded all the gains, including the
advertisement, and the slight increasef since 1890 shows
that for two years past the gains have by a very narrow
margin exceeded the loss, taking all banks together. The
failure of the note-circulation to be elastic is due to the
expense and trouble of buying and depositing bonds to
secure the temporary addition, and withdrawing and sell¬
ing the bonds when the time for contraction comes. Unless
the bonds are withdrawn, the bank has no motive to with- •
draw the added notes.
Since our note-circulation is now kept small by the un¬
profitableness to the banks of further increase (except the
trifling present increase, which may at any time fade out
by disappearance of the narrow margin of gain which
causes it) the way to make room for either elasticity or
permanent increase is to remove part at least of the causes
of the unprofitableness; to relax the checks called 6 and 7
above. Public attention seems to be given to the proposal
to abolish the ten per cent national tax on state bank cir¬
culation; but room for increase may be had just as cer¬
tainly, though not for so great an increase, by reducing or
removing the one per cent tax on national bank circulation,
or reducing the required deposit of bonds, or permitting
the substitution of other securities bearing higher interest.
♦Minor expenses (like examiner's fees), so far as they are independent of the
amount of circulation, may better be included under No. 4; and some which vary,
with the amount, such as the cost of redemption and reissue, are small enough
to be neglected in this article.
t Increase in the true circulation. Notes of abandoned circulation, awaiting
redemption by the Treasury, have no place in such a comparison as this; though
the government reports of circulating money include them in the figures of bank
notes, which thus deceptively show a decrease since 1890.
State Bank Notes.
63
It would take little change of these restraints to cause a
marked acceleration of the increase of national bank notes
that is even now visible. National banks are as ready as
any others to increase their circulation when the increase
pays.
IMPERFECT contraction.
Now let us postpone all the difficulties of securing a
sound state bank currency, and suppose that either by
adopting a system of lightly taxed state bank notes or by
loosening the restrictions upon national banks we make
possible the issue of 100 millions more of secure bank
notes. There is no way of making the issue possible but
by making it profitable. If the checks were so lessened
as to let the profit exceed them before the harvest-season *
came, there is good reason to believe that a part of the
extra notes thus made possible would not only be sent out
but kept out without waiting for the crop-season, unless
certain legal requirements, hitherto unusual, were imposed
upon the banks or certain new conditions attached to the
notes. If this occurred long enough before the crop-season
to permit the swelling of the currency to affect the amount
of coin (either by increasing export or diminishing import
of money-metal), it would to that extent merely substitute
notes for coin lost; the remainder of the "slack" would be
taken up by the growth of business at the crop-season, and
this remainder only would have any value towards giving
elasticity, the former part being a needless and (if extensive
or often repeated) an injurious enlargement of the bank¬
note circulation.
But we will take a case more favorable to the proposal
of a bank note elasticity, and suppose no such wasted ele¬
ment in the new issue; suppose the checks to be so skill¬
fully balanced against the profit that the latter does not
emerge superior till the rate of short-time interest rises at
harvest-time. The new notes then go out, and the first
half of elasticity is thus displayed. But what assurance
♦ For simplicity, the autumnal moving of the crops is spoken of alone, here
and later in the discussion; but the same arguments apply to the spring trade
and to sporadic maxima of business.
64
Colorado College Studies.
have we that when the crop-season is past the excess of
notes will be redeemed and disappear? The apparent answer
is that with slackening of business the currency will be
redundant, bank reserves will be overstocked, and the banks
will have no profitable use for the excess of notes, so that
redemptions will exceed reissues till the whole redundancy
is withdrawn. But this is only an apparent answer. The
redundancy after the crop season is not identical with the
preceding increase of notes; it may be far less; it usually
would be far less in the United States. The growth of use
for money at crop-moving time is in this country a mere
wave in an ascending slope, a slope ascending so rapidly
that we seldom add less than 20 millions a year to our
stock of money, and sometimes 100 millions; the use is
never, except through unusual business depression, so
low after the wave as before it. Almost always, there¬
fore, if we provided elasticity by means of bank notes
unattended by special appliances for forcing their sub¬
sequent withdrawal, and if the elasticity were wholly
by bank notes and no increase of coin shared in it, the re¬
dundancy of money after the crop-season would be less
than the increase of notes during the crop-season. Uon-
ceding that notes equivalent to the whole redundancy were
redeemed and retired, what motive would the banks have
for retiring the rest of the recently added notes? Reserves
have sunk to their normal size, for that is what the disap¬
pearance of redundancy means; the banks have no more
money than they want to use. As fast as notes are re¬
deemed, it is then the bank's interest to reissue them, i. e.
to use the notes in place of the money paid out in redeem¬
ing them. There is thus a part of the recently added
note-supply that will remain in circulation. This process
would be repeated at each maximum of business, and ac¬
cordingly, without such special devices as will presently
be mentioned, an elasticity provided by bank notes alone
would cause an increase of the bank note currency from
year to year.
But it may be that a part of the increase of money at
crop-moving time is in coin. By taking the effect of the
State Bank Notes.
65
mixture upon a period of several years as a whole, we may
eliminate the causes of complication and find a practical
certainty that the note-circulation would show a progres¬
sive increase. For all the effects upon the coin-supply
that the occasional presence of more notes can have are
upon one side, in the direction of making the coin-supply
less than it would otherwise have been. The issue of more
notes at the crop-season will check the rise of short-time
interest and make money easier; in fact, that is what it is
intended for. Easier money means a better maintenance
of prices of goods, and consequently less encouragement
of purchases here by foreign buyers and less tendency to
start an import of gold or a diminution of its export. In
short, the pressure at the crop-season, so far as it is now
relieved by any retention or import of gold, would force
less relief of that kind because the pressure itself would
be less. This, in turn, is only a part of the more general
statement that whenever there is any change in our money-
stock of gold, the presence of recently added bank notes
in the circulation tends to make the increase of gold less
or the decrease more than it would otherwise have been;
for if any given quantity of these bank notes had been ab¬
sent, the tightness of the money-market would have been
increased or its plethora diminished. Taking any period
of years, we may rely upon it that effects of this kind will
have happened while the extra bank notes of the crop-
season were afloat, in which case bank notes will have taken
the place of the coin expelled. And these changes will be
cumulative, because the presence of bank notes always acts
on that side when it acts at all.
means of enforcing contraction.
The importance of this practical certainty that the bank
note supply will increase from year to year if the checks
are so balanced against profit as to permit an easy increase
of notes at every jnaximum of business, and if no special
devices are used to force all the new notes back when busi¬
ness slackens, lies in its strongly commending to us the
use of such special devices if we undertake to make an
%
66
CoLOEADO College Studies.
elastic note-circulation. That a progressive increase of
notes is, on the whole, an evil, most economists will agree.
It is true that there is a gain by use of cheap money when
it is good money; that is, by the less sacrifice of goods
involved in obtaining it, the relative diminution of the
earned part and increase of the note-part. But that seems
to be more than offset by the risks that attend a steady
increase of bank note money—sometimes a distant risk
of an amount great enough to be depreciated, always
a risk of corruption of popular judgment about money
through suggestion of government paper as a resource
at the first pinch, and usually an enhancement (through
enlarging the number of issuing banks and spreading the
habit of extra note-issues) of the greater risk of encourag¬
ing riotous speculation that attends all schemes for elas¬
ticity by bank notes.
As a special device to keep an elastic note-circulation
from increasing progressively, the ingenious suggestion of
the late John Jay Knox * may be considered first: that the
notes added at times of increase should be of a different
color from the others, and should bear interest after a cer¬
tain date. This proposal takes advantage of the well known
fact that notes bearing interest will not circulate as money
except when money is very scarce; the holders naturally
treat them as a sort of bond instead. Mr. Knox's species
of notes would, accordingly, almost all drop out of circula¬
tion as money soon after the date when interest was to
begin. If the notes bore a low rate of interest, they would
find their way to the issuing bank before long; if a high
rate, part of them would be kept by the holders as an in¬
vestment. In the case of a high rate, indeed, the disappear¬
ance from circulation would begin before the date arrived,
and perhaps so soon as to impair the intended elasticity of
the note-circulation.
While trusting to the behavior of the note-holders is
reasonably safe, it seems simpler and more certainly effect¬
ual in every case to provide a legal limit acting directly
* See the Forum, February, 1892.
State Bank Notes.
67
upon the banks. Suppose, for instance, that the increase
of the ordinary note-circulation is prevented by fixing a
maximum for it as nearly as possible at the point where it
now is, admitting hereafter no new issue of notes on the
ordinary terms, except in place of such circulation with¬
drawn;* and that extra circulation be permitted on some
such terms as these—the extra notes to be issued only dur¬
ing two or three specified months just before and during
the crop-season, and the whole circulation of the bank to
be reduced to its former dimensions by, say, January 15
following. The reduction, or its equivalent, may be made
certain by requiring from the bank a deposit of money on
January 15 in place of any excess of notes still outstand¬
ing; the government either to undertake the subsequent
redemption itself, or to return the money to the bank as
fast as the redemption proceeded. The money being kept
idle by the government meanwhile, the effect on the money-
supply of the country is the same as if the excess of notes
had been wholly retired before January 15; and the con¬
traction has begun some time before the date, as the bank,
besides its actual redemption, began to accumulate money
for the final alternative redemption or deposit with the
government. The extra notes could then have precisely
the same appearance as the ordinary notes, and have the
same validity as between the bank and the holder; it would
make no difference whether the notes redeemed and re¬
tired were the same individual notes that went out in the
extra issue; all that is necessary is the retirement of a
certain amount of the notes of that bank, drawn indiffer¬
ently from the old and the new ones. The whole matter
would be settled between the government and the bank,
and no one else would be troubled with any discrimination
among the notes he handles. A second period of possible
issue may be provided for the "spring trade"; but there
should be at least one space of a month or two in each
♦Giving preference to newly organized,banks in allotting this substituted
ordinary circulation; if any were left, old banks that wished to enlarge their
ordinary circulation could have it.
68
Colorado College Studies.
year, and better two such spaces, when the extra circula¬
tion is wholly absent, so that it may have no opportunity
to become permanent circulation and displace coin.* The
hard-and-fast limiting of the ordinary note-circulation
need not exclude new banks from the privilege of note-
issue, for if there are not enough old banks withdrawing*
ordinary circulation to make room for them in the ordinary
circulation, the new banks may nevertheless, by coming
under the inspection-rules, be allowed to share in the extra
issues.
The question how the extra notes should be secured is
of some importance. If deposit of securities is required,
it will be found to impair the readiness of the banks to
issue extra notes; the nearer the formality and expense of
making the issue approached that of the ordinary issue,
the less elasticity the system would give. On the other
hand, if the original security were no more than enough
for the ordinary issue, it would not be enough for a per¬
fect safeguard to the increased amount.f A first claim
upon all the property of the bank, reinforced by a safety
fund and perhaps by a personal liability of the stock¬
holders, would be very strong, but might imaginably fail
in some one or two instances at last; though the govern¬
ment might protect the note-holder by assuming that risk
itself through guarantying the notes, or transfer it to the
other banks in the system through making- them respon¬
sible beyond their share of the safety fund. All these
comments upon the mode of securing the notes apply
equally to Mr. Knox's plan and to the second plan de¬
scribed. So do all the following questions: "What securi¬
ties should take the place of United States bonds when
those are extinct; whether a maximum should be set to the
*/. e. displace coin progressively. There would doubtless be a slight dis¬
placement in the first year or two, and then the coin-supply would go on a little
less than it would otherwise have been, but less by a nearly constant amount.
t But the deposit of securities for the ordinary circulation might be made to
exceed the face-value of the ordinary notes by a margin large enough to cover a
considerable extra circulation. Just now, national banks whose deposited bonds
are 4 per cents could issue 30 per cent, more circulation without exceeding the
market value of their bonds plus their redemption-deposit of cash.
State Bank Notes.
69
extra notes also; whether all banks in the system should
have the extra-note privilege, or banks in certain cities
only; what features of the law should be left subject to
variation by the Comptroller of the Currency or some other
executive officer. There ought to be an arbitrary maxi¬
mum of increase, lest in an occasional time of speculative
temptation the note-issue should run wild; for serious
harm might be done by a rapid increase long before it
reached any automatic check by redemption. Both of the
plans need free criticism and working out in detail by prac¬
tical bankers before either can be trusted; but the point I
wish to urge is, that some such special provision must be
made to insure a return of the note-circulation to its
former volume, or it will probably increase.
In any bank note system, the whole volume of notes
below the lowest point reached in the duller times is dead
and useless for purposes of elasticity. It is only the flow
and ebb that give the elasticity; if the notes never fall be¬
low 100 millions, that 100 millions might as well be coin.*
We may accordingly, if we please, rid ourselves of practi¬
cally all the present ordinary note-circulation, substitute
coin for it, and still have the desired elasticity by using
the extra notes of one of the two plans described above.
Of course the reduction ought to be made gradually, and
by the weight of conditions that do not affect the extra
notes, e. g., by a higher tax.
OBJECTIONS TO STATE BANK NOTES.
It is hard to see why the national bank system, as such,
should be blamed for its failure to be elastic. Any state
bank system must be subject to the same natural laws.
The transfer of supervision to the State governments makes
no change whatever in the rule that the increase or de¬
crease of note-circulation will be determined by the excess
of the profits over the checks or of the checks over the
profits; that rulejs, from the nature of the case, unchange-
♦Except that the change might introduce some additional difficulty into the
arrangements for putting good security behind the extra notes, and the notes
might become imfamiliar enough to be a little less convenient as money.
70 CoLOEADO College Studies.
able. All that can be done is to vary the nature of the
checks; and wherever that can be done by the state gov¬
ernments it can be done by the national government. If
it is desired to increase the note-circulation, that end is
reached as certainly by removing taxes from national bank
circulation as by removing them from state bank circula¬
tion. If it is desired to make temporary contractions easier,
by reducing the expense and trouble of withdrawing de¬
posited bonds and redeeming the notes, or to adopt the Knox
plan or the second plan described in this article, every
detail of the improved process can be applied by the na¬
tional government as easily as by the state governments,
and indeed with less expense. Anything that would be
dangerous in a national bank note system would be as
dangerous (and usually more dangerous) in a state bank
note system. And any imaginable gain under state super¬
vision can be had as well or better under national super¬
vision.
The diflBculty of framing a good system of bank note
law and supervision by forty-four distinct legislatures needs
no detailed discussion, unless by a competent humorist.
There is no hope that a jumble of various state-systems
would " average up" into a good bank-note circulation. If
in ten states, five states, one state, the system is bad,
there will appear bank notes imperfectly guarded by secu¬
rities or dependent upon too small a reserve, in which case
it is only a question of time when some bank will let its
notes go to protest; to say nothing of the moral certainty
that the wish of the legislatures to see the new system well
started would cause the checks upon profits to be set too
low, so that (taking the country through) there would be
a large unnecessary original issue of notes, coming before
any need of trade called for them, and merely crowding
out better money.* In whatever states the notes were
insecure, those states would suffer annoyance and occa¬
sional loss by circulation of such notes; some of the notes
* This point has not received the attention it deserves. Its practical impor¬
tance is great.
State Bank Notes.
71
would pass into other states and carry annoyance with
them; and the repute of good notes would be injured out¬
side of the state of their origin, because many men would
not take the trouble to remember which states were sound,
and would look with distrust upon any notes of a distant
state, perhaps of any state but their own. Unless all the
states agreed upon the same paper and similar printing,
the detection of counterfeits would once more become a
fine art, and the unskilled man and woman would be daily
exposed to loss. It is not enough to answer that there is
no danger of the return of the absurd and dangerous bank
money of the first half of the century; if there is any
failure to redeem notes, any discount upon some notes of
distant origin or of tarnished fame, the opportunity of
petty fraud upon the ignorant and careless is thrown wide
open, and every man must choose between possible loss
and the vexatious precaution of examining every note he
receives. Moreover, the workman in taking wages, the
retail dealer in taking payment from a customer he is
anxious to retain, is often reluctant to give offense by ob¬
jecting to money on the mere chance that it is depreciated,
and will sometimes take it when he knows there will be a
small depreciation, rather than raise the objection. The
presence in any money system of elements that are dis¬
trusted, that must be looked for and chaffered over or sub¬
ject the recipient to loss, is so wearisome an addition to
the friction of trade that a clear case of beneficence in
other directions (and no small beneficence) must be shown
to give such kinds of money any claim to consideration.
And when such beneficence as state bank notes are capa¬
ble of can be had without the friction and annoyance by
using national bank notes instead, the attempt to substi¬
tute the former seems a ludicrous folly. Even if we im¬
agine the prodigy of wise concurrent action of all the
states at first, what guaranty is there against the appear¬
ance from time time hereafter of those legislatures whose
pride it is to despise experience, to brush aside the sophis¬
tries of prejudiced conservatives, and to open short cuts to
72
CoLOBADo College Studies.
prosperity for the oppressed plain people? Many of the
advocates of restoration of state bank notes see the diffi¬
culties distinctly enough to propose that there shall still
be some national restriction and supervision. The best
that can be said of such plans is that a safe built partly of
iron and partly of v?ood will resist fire better than a safe
built wholly of wood. The advocates of an admixture of
wood may fairly be asked what good is expected from the
change.
If we are to attempt elasticity, then, common prudence
requires the preference of national bank notes to state bank
notes; for any tolerable system of so-called state bank
notes must include national control so nearly complete
that it is really a national bank note system.
III.—mCEEASE OF SCANTY LOCAL CIECULATION.
So far as it deals with the increased demand at crop-
moving time, this argument for state bank notes is of course
mere repetition of the argument from elasticity; but a
separate place may be given to it because some persons
have seriously urged that the permanent stock of money
could thus be increased in the regions where a scarcity is
now felt. Taken in this sense, even, it is completely an¬
swered by the answer to the elasticity argument; for if
there is any way by which state bank notes could give a
larger permanent money circulation to parts of the country,
the same way can be provided for national bank notes by
national law and supervision. And if this were not so,
the proposed advantage of a larger local circulation is im¬
aginary. Money is sent away from districts where capital
is scanty because goods are so valuable to the farmer, the
trader and the manufacturer, that they prefer having more
goods to keeping a comfortable cash reserve in hand or in
bank; indeed they usually borrow besides. Double the
money in such a district, and within two months there
would be little more than at first, if it were money that
could be used in outside payments; in the long run there
State Bank Notes.
73
would scarcely be more, unless it depreciated, than if the
addition had never been made. A district within a coun¬
try can no more enlarge its permanent circulation by issu¬
ing paper than the country itself can; whatever nominal
enlargement may appear will be caused by depreciation.
Even a nominal permanent enlargement could be had only
through notes that were objectionable outside and were
issued in such volume as to exceed * the formerly normal
amount of money in the district; until they reached that
volume they would merely displace other money. With a
circulation thus enlarged, the district would enjoy all the
blessings of a depreciated paper currency and a varying
rate of exchange with the outside world; and unless the
district had a well defined frontier line, which is improb¬
able, there would be a strip of country all around it where
the notes would be the cause of daily disputes and frauds.
If we want this state of things, we can have it; but we can
give the local banks free rein just as easily by national law
as by state law.
IV.—EVILS OF THE TEH PER CENT. TAX.
The objection to the tax on state bank circulation ap¬
pears in two forms. One of these, urging that individual
liberty is unfairly dealt with by a prohibitory tax on bank
notes that fail to conform to legally set rules, must be the
product of hasty writing without second thought. Surely
the creation of money is, like marriage, "affected by a
public interest," and subject to the right of the whole
community to protect its interest by prescribing conditions
for every such transaction. Does any one (except those
who follow their truth wherever it leads, with a Tolstoi¬
like disregard of consequences and of other truths) pro¬
pose that every mushroom bank or factory store shall
be left free to circulate its notes or "orders" as money
where it can? If not, some power must prohibit, and prac-
*
* Strictly, of course, allowance must be made for the scattered remains of
the former money, and conversely for the increasing needs of trade. And to cause
the inflation the notes must become practically inconvertible.
74
CoLOBADo College Studies.
tically the power must be either the Nation or the State.
Here rises the other form of the argument: that the pro¬
hibitory tax goes beyond the constitutional powers of Con¬
gress. Such a claim can be maintained only as a protest
against the decision of the Supreme Court, like the still
existing dissent from the Legal Tender decision. There
is no room for the claim of "moral" unconstitutionality,
such as there might have been if the Court had merely
sustained the law in its formal aspect of laying a tax, for
the decision was not reached by ignoring the prohibitory
nature of the tax, but by affirming the power to prohibit.
The words are: "Congress may restrain by suitable enact¬
ments the circulation as money of any notes not issued
under its own authority." Ought Congress to retreat be¬
fore constitutional scruples which have (to state the case
mildly) nothing near unanimity of legal opinion to sup¬
port them and have already been overruled by the Supreme
Court, scruples which at best affect merely the question
whether Congress or the State legislatures shall use a power
that one or the other must use; when the abandonment of
the field by Congress would expose the country to the in¬
evitable evils of disjointed management of note-circulation
by the separate States? If any one holds that decision of
the Supreme Court to be erroneous, he might better aim
to cure the error by a constitutional amendruent than to
put upon the country the needless and ridiculous embar¬
rassments that state bank paper would inflict.
Between national bank notes and state bank notes, then,
the choice seems too easy to be called a problem. The real
bank-note question is whether we need any bank notes at
all; and if we do, how, under national control, they can be
kept secure and their volume can be made elastic. The
latter part of the subject has had a fairly full public dis¬
cussion, but too little attention has been given to the pos¬
sibility of doing without bank notes. That the withdrawal
of the present stock of bank notes would not probably be
State Bank Notes.
75
a troublesome process, has been shown in the earlier part
of this paper. And if it is thought necessary to secure for
the money-supply an elasticity of volume, in addition to
the existing virtual elasticity by change of speed in circu¬
lation and by additions of metal, it is possible to have
ELASTICITY WITHOUT NOTES.
Our choice of means is not restricted to notes. The
Treasury itself is a ready-made apparatus. Whenever
Treasury receipts exceed Treasury payments, the circula¬
tion outside contracts;* whenever the payments predomi¬
nate, the circulation enlarges. When such a change comes
without any corresponding need of trade, the disparity is
set right by the usual automatic methods, i. e. by a quick¬
ening of the average speed of circulation or an increase of
bank reserves in the cases of needless contraction and ex¬
pansion respectively, followed (if the disparity is large
enough and lasts long enough) by a change in the rate of
short-time interest and ultimately by a change in the ex¬
port or import of metal. When the expansion or contrac¬
tion happens to fit a need of trade, we have a true elasticity
imparted by the Treasury action. In fact, several impor¬
tant outpours and absorptions of money by the Treasury
occur every year; if they could be made to fit the needs of
trade better than they do now, the circulation would be
made elastic pro tanto. For instance, nearly all the in¬
terest on the public debt is paid in April and the corre¬
sponding quarter months, now that the interest-bearing
debt is mostly the 1907 four per cents. If the interest were
made semi-annual, and payable in March and September,
about 11 millions t of interest-money would be cast into the
channels of business at crop-moving time, and another 11
millions in time for the spring trade, while there would
be a corresponding contracting infiuence at work through
♦Contracts relatively; that is, if greater forces are just then expanding it,
Treasury action merely diminishes the expansion. The word enlarges," in the
next phrase, is used ift the same relative sense, though the enlargement is usually
absolute also.
t Instead of the present arrangement of 514 millions in October, and 514 more
in January, when it is not wanted.
76
coloeado College Studies.
the summer and the winter, when it is wanted. Again, the
pensions are paid quarterly, but are distributed in groups
upon different sets of quarter-days. These might be so
grouped, probably without serious inconvenience to the
pensioners,* that the payments in two months of spring
should be about twice as large and in two months of autumn
about three times as large as at other times. With pen¬
sions amounting to 160 or 180 millions annually, such an
arrangement could be made to "plump" an extra 30 or 40
millions in the autumn and half of that in the spring.
Without recommending these particular methods, one may
take them as illustrating the possibility of such adjust¬
ments. Other means, some of which are applied by the
Treasury, are the purchase of bonds at the end of summer,
the increase of Treasury deposits with the banks, the ar¬
rangement of contracts so as to make the principal pay¬
ments for supplies in the autumn and spring.
It is a fair question for debate whether this paternal-
looking behavior of the Treasury would be good policy in
the long run. The objection to it as government inter¬
ference is sound. But as compared with the present Treas¬
ury methods, it would be only a better arrangement of ebbs
and flows that exist already in considerable degree and
often at the wrong times.t Whatever evils it has, the
Treasury method of obtaining elasticity is perhaps better
than any known bank-note system, and is far better than
any possible state bank system. In the long run, among
fallible men, expensivp money is the most economical;
money that cannot be duplicated without a liberal expense
of labor; metal, or certiflcates known to have their full
equivalent of metal behind them. In the sacriflce a coun¬
try necessarily makes to obtain such money, as compared
♦Crudely, by making a part of the pensions semi-annual, with the autumnal
payment larger than the other; an inequality that fits tolerably well the needs of
indigent pensioners.
t See illustrative figures in Mr. Kinley's article on the Independent Treasury
in the Annals of the American Academy of Political and Social Science, Septem¬
ber, 1892. The figures are for operations at New York, but are a suflBcient indica¬
tion of what happens in the whole country.
State Bank Notes.
77
with watering it by a note-element, it is buying business
security and a charm against popular delusions. Some¬
thing might be said, even if no project for elasticity
through Treasury payments is accepted, for the belief
that our best policy is to prefer safety to elasticity, to
arrange the checks on profit sd as to insure the gradual
extinction of the bank notes,* to substitute nothing for
them, and so let coin fiow in; when that is done, to increase
the coin reserve against greenbacks by 15 or 20 millions
annually till it equals the whole volume of greenbacks and
they can be converted into coin certificates. When a gen¬
eration has grown up that has never seen a bank note or a
government note, the seed of many a folly will be dead in
the popular mind.
The principal conclusions we have reached may be
summarized as follows:
1. The extinction of the national bank notes requires
no creation of other money. The coin to take their place
will come in without perceptibly greater national sacrifice
than has attended the extinction of a still larger amount of
notes in the past few years.
2. An elastic bank note system would probably cause
progressive increase in the amount of note-circulation,
unless restraints hitherto unusual were applied. Such re¬
straint might be given by causing the notes added in the
temporary expansions to bear interest after a set time, or
by expressly requiring the issuing banks to reduce their
circulation within the old limits before a set time.
3. Nothing is to be gained, either towards elasticity pr
towards permanent enlargement of local circulation, by
substitution of state control for national control. The in¬
crease or diminution of bank notes is determined by the
relation between the profits and certain well defined checks,
and the state governments cannot apply the checks better
than the national government can.
* Which of course does not imply a disappearance of the national bank system.
78 Colorado College Studies.
4. The relegation of control to the states would almost
certainly cause the checks to be set too low at first, and
cause a large initial increase of notes.
5. Insecure notes from a single state would diminish
the practical convenience ^f the whole note-circulation.
6. Security of all the notes under separate state man¬
agement is almost incredibly improbable; and if attained
in one year, might easily fail in the next.
7. The prohibition, by tax or otherwise, of circulating
notes that fail to conform with national law, is not an in¬
justice to individuals. The objection on constitutional
grounds touches only the question whether state or na¬
tional legislatures shall impose the necessary restrictions;
and if sound at all, is rather an argument for a constitu¬
tional amendment than for a bad money system.
8. A means of elasticity, probably safer than any bank
note system, exists in the irregularity of Treasury expenses.
(Colorado (^ollege,
Colorado Sprit^gs^ Colo>
College offers two courses, leading, respectively, to
^ tlie degrees of Bachelor of Arts and Bachelor of
Philosophy. In the Ph. B. Course, Greek is omitted and
more attention is given to the sciences and modern lan¬
guages. The College has a good library and well-equipped
laboratories.
The various courses of study have been so arranged
and the faculty so enlarged that Colorado College offers
the same educational facilities as the Eastern colleges.
For catalogues, address t-. „
® ' Wm. F. Slocum,
President.
The Cutler Academy,
Under the auspices of the Colorado College, gives students
a thorough preparation for admission to the Freshman
class of any college in the country. Correspondence con¬
cerning the Cutler Academy should be addressed to the
Assistant Principal, ^ Gile
The Location of the College is unsurpassed. Colorado Springs
has a world-wide reputation as a Health Resort.
Students forced by pulmonary or malarial troubles to
discontinue their studies in the East, pursue college courses
here successfully and at the same time make a permanent
gain in health.
THE COBURN LIBRARY.
FIFTH ANNUAL PUBLICATION.
Colorado College
Studies.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLO.
1894,
OFFICERS, 1894.
President,
Vice-Presidents,
Secretary,
William Stkieby.
{W. M. Hall.
/ Louis R. Ehrich.
Plorian Cajori.
Treasurer,
Frank H. Loud.
TABLE OF CONTENTS.
PAfiE
The Ethical Problem op the Public School System.
By TV. F. Slocum, Jr., 1
The Origin and Use of the Natural Gas at Manitou,
Colorado. By William Strichy, ------ 14
Herpetolooical Notes from Kansas and Te.xas.
By F. TT^ Crag in, - - - 37
The Choctaw and Grayson Terranes of the Arietina,
By F. TV. Crugiii, 40
Descriptions op New Species of Invertebrata from
the Comanche Series in Texas, Indian Territory,
and Kansas; with Definition of two Comanche
Terranes. By F. TT'. Crag in, ------- 49
Vertebrata from the Neocomian of Kansas.
-By F. TV. Cragin, --------- 09
THE GAZETTE PRfNTtNG CO. COLORADO SPRINGS.
THE ETHICAL PROBLEM OF THE PUBLIC SCHOOLS *
BY WILLIAM FREDERICK SLOCUM, JR.
The political instincts of the people of the United States
have led them to seek the best possible system of public
schools, and the supreme motive for the expenditure of the
vast sums of money that have been voted with great willing¬
ness for their foundation and their continued support has
been the education of the youth of the country for citizenship.
The final test of all citizenship must be an ethical one; and
especially is this true in a democracy where the stability of
its life depends upon the character of its citizens. With this
fact in view, it is pertinent to ask whether the public schools
are fulfilling the mission for which they were founded.
There has been for some time an increasing interest in
the moral aspect of the public school problem. One indica¬
tion of this is seen in the appearance during the last two years
of seven rather notable text-books upon ethics, especially
designed for schools of lower grade. The question that is
now asked, however, does not find its answer in any reply
given to the query raised as to the wisdom of publishing
these books, for it seeks to go behind the inquiry. Should
ethics be taught at all to boys and girls of the age of those
in the public schools ? It asks whether the problem of public
morals is involved in the very nature of the system as such.
No one denies that the education of the thirteen million
children in these schools has much to do with the destiny of
the republic, nor that the country has placed its future, for
good or evil, in tlie hands of the public school teacher.
The church inay have the capacity for the moral training
of the youth of the country; but, great as is its influence, the
ethico-religious movement is not at present far reaching
* Reprinted from The Atlantic Monthly, May, 1894.
2
COLOKADO COLLEGE STUDIES.
enough to fashion even the majority of these thirteen million
pupils into citizens in whom righteousne.ss shall be the con¬
trolling element; and there is no reason for thinking that it
will be in the immediate future.
The home comes much nearer meeting the need; but
doubtless Mr. G. H. Palmer's statement is correct, in his
article Can Moral Conduct be Taught in Schools? "The
home," he says, " which has hitherto been the fundamental
agency for fostering morality in the young, is just now in
sore need of repair. We can no longer depend upon it alone
for moral guardianship. It must be supplemented, possibly
reconstructed." It still does, and always will, train the choice
few for leadership; but after enumerating the homes in which
the best that was in Puritanism still is the controlling ele¬
ment, and those that develop morality by means of the self-
respect engendered by intellectual and aesthetic culture,—in
fact, all those in which high ideals predominate,— there is
still left a vast number where self-seeking is the main principle
of life. If to the number of children in these latter homes
are added the thousands who exist with scarcely any trace of
home life to shelter them, we shall be forced to admit that
there would be a moral crisis if the public school were not
doing its beneficent work.
The question still awaits us, however. What is the public
school system achieving for public morals?
Just at present there is a movement in various quarters to
introduce instruction in the theory of morals into even the
lower grades of the schools; but no one seems to be sure that
this will not produce self-conscious prigs, or encourage morbid
introspection rather than sturdy morality. But all are agreed
that it is the function of the public schools—not to say of all
schools, for that matter—to produce what some one calls
" unconscious rectitude " in these thirteen million children.
All appear to believe that development of morality is essen¬
tial, and few that the teaching of mere ethical theories will
be of much value.
The problem involves, then, the study of the system as a
system from the standpoint of practical morality, to see if it
V
THE ETHICAL PROBLEM OF THE PUBLIC SCHOOLS. 3
is a moral force in and of itself. Its power for righteousness
depends upon what it is by virtue of its plan, purpose, and
scope; upon its spirit, genius, and the manner in which it is
realizing the ideal that has brought it into existence.
It is not possible at present to make a comprehensive and
accurate study of the moral value of the public school system.
The method of examination must be inductive, and the con¬
ditions vary so greatly in different communities that it is
exceedingly diflBcult to reach conclusions that are drawn from
a sufficiently large number of facts to make one's deductions
satisfactory. The literature upon the subject, and in fact
upon the general subject of the public schools, especially
from a sociological and economic point of view, is exceedingly
meagre. A good illustration of this point is the article in
the ninth edition of the Encyclopedia Britannica, where, in
over one hundred of its large and closely printed pages upon
the United States, less than quarter of a page is devoted to
this institution, and even what is written is of no special
value. Such papers as the articles of Dr. Bice which have
lately appeared in The Forum will furnish the basis of other
work, and encouragement should be given to such critical
examinations of the system; but much more work of this
nature must be done before a comprehensive and discrimi¬
nating thesis can be written upon the real influence of the
public schools upon the morals of the country.
Certain conclusions, however, in regard to their power
can be reached, and these ought to be stated in an article
attempting to give a judicial opinion of their ethical merits.
First there should be indicated the points both of direct and
of indirect ethical value, and then the lines of weakness or
of positive failure.
Modern psychology, leading to the study of the objective
manifestations of mind, tells us that " habit covers a very
large part of life;" that instincts are simply habits to which
there is an innate tendency; and that these habits are due to
what is characterized as the "plasticity" of brain matter to
outward influences. Whether, for example, as one of our
distinguished writers upon psycho-physics has told us, the
4
COLORADO COLLEGE STUDIES.
habit of putting one's hands into one's pockets is mechanically
nothing but the reflex discharge, or not, the fact remains
that " the walking bundle of habits of later years " does spin
his fate for good or evil in that plastic state which covers the
time when the child is usually a pupil in the public schools.
If this is true, there is reason for saying that there is ethical
value in the systematic order and discipline that are found
in the majority of these schools. The constant and punctual
attendance, the orderly arrangement of pupils, together with
strict requirements in connection with these matters, fit one
for successful business life, and create a sense of responsibility
in regard to the use of time. The system of the public schools
tends to make the pupil systematic, and helps to produce the
accurate and methodical man or woman of later years. The
testimony in regard to this is incontrovertible.
More than this, however, there is ethical value in the very
conception from which the movement started, and the idea
along which it has developed. The notion of self-improve¬
ment for a high end has in itself moral worth; for it demands
that the youth of the country shall be upright not only be¬
cause excellence of character is a good in itself, but because '
it promotes the good of the state. The expenditure of such
a large proportion of the public revenues, the erection of so
many buildings, the employment of such large numbers of
high-minded persons, the creation and constant support of
such an elaborate scheme, for the one purpose of producing
good citizens, are object lessons that must have great influence
upon the public.
What has been said indicates some of the lines in which
the schools exert a direct moral influence; but in addition to
this a large amount of testimony shows that, especially where
there is a compulsory school law, a sense of responsibility
has been developed in parents, making them recognize their
own obligations. This, the reflex influence of the public
schools upon the communities in which the system is at its
best, is shown in many ways. Parents whose education has
been meagre and faulty have become learners themselves,
and have been led for the first time to consider seriously the
THE ETHICAL PROBLEM OF THE PUBLIC SCHOOLS. 5
duties and future of their children; and this thought for the
welfare of others has had a wholesome reaction upon their
own lives.
In naming the elements that give moral value to the
public schools mention should be made of the indirect good
accomplished by keeping large numbers of children from the
haphazard companionship of the streets, and from idleness
and degrading influences. Especially in the larger towns and
cities has this been true. To this negative protective good
should be added the positive advantage derived from the
acquisition of habits of neatness, personal cleanliness, and,
in many schools, good manners.
After enumerating these things, which are more or less
incidental to the system, and others that might and ought to
be considered, it still remains to be said that the greatest
ethical value in the public school system is, and must ever be,
the intellectual work that is accomplished by it. There can
be no doubt that there is a great amount of teaching that is
not only unmoral, but positively immoral, in its direct or
indirect influence. Recent publications demonstrate this
fact, and show that the public schools will be at their best as
a moral force when their work is thoroughly scientific.
Their success, then, in achieving the purpose for which
they have been created depends primarily upon the character
of the instruction that is given in them. It may be true that
" pupils will not learn their lessons in arithmetic if they have
not already made some progress in concentration, in self-
forgetfulness, in acceptance of duty;" but it is equally true
that mental exactitude and thoroughness of work, under the
influence of a teacher whose method is scientific and whose
spirit is earnest, will develop the elements that produce con¬
centration, self-forgetfulness, and dutifulness. The tendency
of mechanical, unscientific instruction is towards immorality.
Schools that are^mder the control of selfish officials, with in¬
competent supervision and antiquated methods of teaching,
have no power to quicken those springs of action which are
the sources of morality. On the other hand, ethical capacity
and moral strength can and ought to be produced by a high-
6
COLOBADO COLLEGE STUDIES.
minded instructor in and through the very process of teaching
arithmetic, grammar, and geography. Mental activity and
intellectual self-respect are important factors in the truest
morality. Habits of attention and observation may be de¬
veloped into self-control, and the power of judgment into
capacity for distinguishing between right and wrong. The
ability to hold one's self uninterruptedly to any task may be
power for resisting wrong or for the performance of duty.
In this connection mention should be made of a certain
force of character which may be produced by the element of
continuity in the courses of study through which the pupils
are required to pass. So far as these are fitted to the nor¬
mal, natural method of mental growth in the pupil they have
ethical value. Obedience to the laws of mental development
is essential to the highest type of manhood, and abnormal,
restricted, unnatural mental growth is apt to produce im¬
morality.
The things that have been mentioned lie on the hopeful
side of this problem, and on the whole they make the outlook
encouraging. They lead, however, to the question. How can
an institution that is fraught with so much good, and which
is necessary to the life of the state, be still further improved,
and how can certain evils within it be eradicated? To do a
little in the effort to answer this question, and also that this
statement of the moral problem of the public schools may not
be one-sided, an examination must be made of the evils that
at least modify their usefulness.
Dr. Rice says, in his last article on Our Public School
System: "One half the work of placing the schools upon a
healthful foundation has been accomplished when the mem¬
bers of the boards of education become endowed with the
desire to improve the schools." To accept as final the opinion
that they are perfect always results in the evil elements be¬
coming conspicuous. The most dangerous official is the one
who regards no criticism as valid simply because it is uttered
against the public schools. Neglect of such an essential
institution is not worse than bigoted satisfaction with it and
all that pertains to it.
THE ETHICAL PROBLEM OF THE PUBLIC SCHOOLS. 7
The pride of its friends is that it is a great system of
education. Mention has already been made of the value of
the element of continuity in a course of study, but there is
also a difficulty connected with it that cannot be ignored. The
fixed schedule of study is fixed for all; the long courses are,
with few exceptions, unmodified for the slow or the quick
minds. The only reply the writer has been able to secure to
the question, "What can he done to remedy this?" has been,
" There is no escape from it, except in a few cases where very
unusually bright children are promoted more rapidly than
the others." The time taken for many children of more than
average ability to complete a subject is unreasonably long;
but the nature of the child must bend to the system, the system
little or not at all to the peculiarities of the pupil. Now,
nothing is more important, in creating and preserving
" unconscious rectitude," than the element of spontaneity,
and there can be no doubt that many children who pass
through the long years spent in the public schools lose in
this respect rather than gain. The kindergarten is obviating
this danger somewhat; but wherever there is a suppressed
mental life there must exist, in some degree at least, a sup¬
pressed moral nature: there is a logical connection between
the inflexible system that holds a responsive, sensitive child
in its grasp for years, and mental reactions that too often
develop into moral weakness, and occasionally into vice.
This tendency is, no doubt, not entirely the fault of the
system,-as a hard-and-fast system, but in a large degree of
those unscientific methods which merely tax the memory,
stunt rather than develop the reasoning faculty, and usually
make the child unhappy, and sometimes morbid. President
Eliot has shown that there is a waste of time in the student
life by keeping pupils too long on subjects that should be
covered in a much shorter period. But this loss of time has
a more important bearing than the one which he considers.
The attempt to *ave time is important; the attempt to save
the moral nature is far more important. The destruction of
interest and enthusiasm in a child has more than an intel¬
lectual significance; it interferes as well with his moral de¬
velopment. If one believes that there are certain definite
8
COLOEADO COLLEGE STUDIES.
laws for the growth of the soul, which have been discovered
by the world's great teachers, he ought also to believe that
the violation of these laws in the training of children must
react on the moral as well as on the mental life of those who
can least afford to pay the penalty. The destruction of in¬
dividuality" brutalizes a nature, and there is constant danger
of this where mere system is conspicuous and becomes the
controlling element. It is exceedingly difficult for an in¬
structor to hold the interest and develop the enthusiasm of a
pupil after an appropriate amount of time has been given to
any one subject; and although it is true that the teacher is
the most important factor in connection with the system, and
that sing-song recitations and pure memorizing will, under
any condition of affairs, produce unscientific results, yet the
best teacher is influenced by the system under which he
teaches. There can be no doubt that many children who
pass through the long years of continuous school life lose in
some degree the quality of spontaneity, and that the loss of it
is accountable for the lack of some of those finer sentiments
that have always been the glory and the beauty of human life.
No discussion of thq moral problems of the public school
system would be satisfactory if reference were not made to
what has, perhaps somewhat exaggeratedly, been called " the
pauperizing tendency of the public school system." Free
tuition has led to free text-books, until the principle has been
clearly laid down that the state must furnish, without charge,
to all its children whatever education they desire. Especially
in the West has this been carried to its logical extreme, and
the state university is asked to provide the highest special
education not only without charge for tuition, use of build¬
ings and apparatus, but in some cases with free rooms that
are furnished and warmed at the expense of the state. In
other words, it is claimed that no money equivalent should
be given for the benefit received and the service rendered.
Parent and pupil can take from the state, but, except what
the pupil may return through his better preparation for
citizenship, nothing is to be given for that which has been
bestowed; and with large numbers of persons there is no
THE ETHICAL PROBLEM OP THE PUBLIC SCHOOLS. 9
sense of obligation whatever in the matter. It is said by
those who oppose the extreme form which this theory has
taken that it carries the paternal feature of government to a
dangerous extent; that it makes the citizen selfish and grasp¬
ing; that it may, and in many cases undoubtedly does, minis¬
ter to that spirit which characterizes much of our American
life,— the spirit that ever asks. What shall we have? and
seldom. What shall we give? and which is the bane of our
present social order. It is further claimed that the results of
this are already apparent in our national life; that the spirit
which made our pension system is encouraged and developed
by the " pauperizing tendency in the public school system."
• Although it has been difficult to secure accurate informa¬
tion in regard to the results of this " free element " in educa¬
tion, it has become only too evident that many parents look
upon the teachers as if they were servants; demanding every¬
thing from the school without any idea that they owe anything
in return. Such facts as these—and there are many others
which might be cited—indicate some of the evil results of
the plan, and make it very clear that here is an actual danger
to the higher ethical conditions. We should carefully guard
our national life at this point.
There seems to be no escape from this free element and
its logical results. All that can be done is to ward off the
possible danger by constantly holding before the pupils the
idea that they must repay the state in good citizenship.
Impurity may not be a greater evil in public than in
private schools; but there are certain conditions in the demo¬
cratic commingling of children in the former which make it
more than a possible evil. There can be little or no social
distinction except that growing out of the location of the
school buildings. There is the "uptown" and the "down
town" school; but if a pupil is admitted into the schools at
all, there can be*no law requiring him to be in one building
rather than in another, except the regulation that arises from
residence in a particular locality; and even this is not enforced
in some cities and towns. The very idea of the public school
makes any classification upon social and ethical grounds an
10
COLORADO COLLEGE STUDIES.
impossibility. There are localities where this evil of impurity
is nothing more than a potential danger; but there are very
many others where it is a real evil. On the part of teachers
there is a growing intelligence concerning it, and a greater
vigilance in guarding against it. Those who do realize its
enormity, and meet it aright, have secured results that ought
to encourage all others; but there should be a most stringent
requirement in this matter in defining the teacher's duties.
In some of the best normal schools the students have the
plainest and clearest instruction upon this subject. They
are told the habits for which they are to watch, and the best
ways to meet the evil of impurity in whatever form it is
present among children. But such preparation is far from
universal. Not many years ago, a graduate of one of these
schools said that the teacher who gave her class instruction
on this subject asked its members how many of them had
not known of at least the existence of a vile vocabulary
among their schoolmates. All but two of the large class re¬
plied that during their early life in the public schools they
had heard what they could never forget, though no words
could express the longing they felt to blot it from their
memories; and in looking back from their more mature stand¬
point, it seemed to them that the teachers must have felt no
special duty in the matter. These were young women from
the public schools of one of the older States. There is no
doubt, however, that each year our public school teachers
have an increasing sense of responsibility for purity in
thought and word of the children under their care.
The difficulties with which they have to contend are very
great. The two or three children who, with an air of mys¬
tery, bring information in regard to forms of impurity have
great power for mischief, especially when they put a base
interpretation upon things that are in themselves pure; and
the quick imagination of a child, together with the fact that
this information is not guarded, as it would be if it came
from an older and a wise person, makes it doubly dangerous.
The testimony of one teacher, which has been repeated by
many, is to the effect that the large majority of children in
THE ETHICAL PEOBLEM OP THE PUBLIC SCHOOLS. 11
the public schools know, theoretically, as much about the
forms of impurity at twelve and fourteen as they ever will.
Thus the situation calls for teachers wise in heart and head,
watchful in regard to this danger, and skillful in meeting it;
for the sense of disgrace that comes to many children from
the mere acquisition of this information is a blow to that
peculiar' delicacy of feeling which exists with the highest
morality. In many cases the inherent force of home training
preserves the child from radical injury; but some children
never escape the wrong that is done them, others are led into
practices that seriously modify their usefulness, while still
others are ruined.
The public school is a normal outgrowth of our social and
political order, and its tendencies are the logical outcome of
this order. Its dangers are those that exist in this democratic
state, but it lies in the power of the schools to eradicate much
of the evil in the state. It is difficult to say how this is to be
accomplished, but certainly the most effective method will be
along the line of the general improvement of the system.
This improvement will be brought about by the divorce of
the control of the schools from partisan politics; by the ap¬
pointment of teachers for merit only, merit in which force
of character should be regarded as a sine qua nonj by the
introduction of scientific instruction to the exclusion of
mechanical methods; and by constantly making prominent
the idea that the pupils are being fitted for citizenship and
actual service. Something could also be said in regard to
the necessity of a larger number of teachers, in order that
the element of personal influence may be greater and more
immediate.
As this paper is only a statement of the ethical problem
of the public schools, and not an attempt to solve it, it is
not within its province to discuss the many possible remedies
that have been Suggested by teachers and others who are
studying this question. Few hesitate to say that there are
defects in the system, and possible moral dangers associated
with it, against which our national life should be guarded
with great wisdom and persistence.
12
COLORADO COLLEGE STUDIES.
The public school stands in close relationship to every
moral problem in the republic. The problem of municipal
government is pressing upon thoughtful citizens to-day, and
many schemes are devised to make it impossible for dishonest
politicians to practice their dishonesty and selfishness; but a
radical cure of this and all other evils in the body politic
can be effected only by the creation of upright citizens. A
majority of the voters receive their only training in the public
schools. If low and selfish aims rule their conduct; if they
lack the possibility of enthusiasm or a high purpose; if, in
short, their lives are wanting in principle, it is not enough
to say that demoralizing influences overthrow the good
wrought within the schools, because the business of the
schools is so to establish morality that it cannot be ovet-
thrown by evil circumstances in after life. For, as has already
been pointed out, the church and the home of the present day
are not able to perform this work, and therefore the schools,
because of the very idea which underlies their foundation
and secures their continued support, and because of the
amount of time which the child necessarily spends in them,
must be held largely responsible for the foundation of char¬
acter; in other words, for the training of upright and patriotic
citizens. This, as has just been said, is their husitiess. School
boards apd teachers are needed who realize this important
fact, and who are willing and able to make the development
of principle the central point in their work.
No one who examines carefully the present political and
social order can fail to notice that there is a spirit of self-
seeking abroad that is destructive of the noblest virtues and
the highest ethical conditions; that vast numbers of citizens
are controlled by the passion for getting rather than for
giving. This is the dangerous element in the social problem.
It is the bane of that partisanship that is ever willing to
sacrifice the state for party supremacy; it is the moral
obliquity of the pauper and the criminal, who are ever seek¬
ing to get something without rendering a fair and just equiva¬
lent. Is the public school laying its foundation deep enough?
Has it struck its roots into the moral nature of these thirteen
THE ETHICAL PROBLEM OF THE PUBLIC SCHOOLS. 13
million children? These are the questions that serious and
earnest people are asking. There is a striking similarity be¬
tween the excellencies in our national life and the excellencies
in our public school system. There is also a striking simi¬
larity between the evils in both. Can it not then be said that
the eradication of the evils in the public schools will have
very much to do with their eradication in the life of the state?
To touch the springs of action in these pupils is to touch
the very sources of power in the national life; and there is
no opportunity to be compared with that offered by the public
schools. The institution is so sacred, so far-reaching in its
influence, that it must be rescued from political strife and
partisan narrowness.
*
THE ORIGIN AND USE OF THE NATURAL OAS AT
MANITOU, COLORADO.
BY WILLIAM STBIEBY.
The waters of the mineral springs at Manitou owe their
sparkle and piquancy to the carbonic acid with which they are
naturally surcharged. The beautifully clear water as it issues
from its subterranean channels is accompanied in several of
the springs by a considerable flow of exceedingly pure carbon
dioxide. When dipped from the springs it continues to
effervesce for some little time, and the agreeable flavor of the
gas makes the drink very palatable in spite of the large
quantity of alkaline mineral matter which it holds in solution.
For many years these springs have been locally esteemed
as furnishing both a refreshing beverage and a valuable
medicinal agent, but it is only within the last six or seven
years that the bottled waters have been put upon the market
to supply a wider circle of admirers. In order to give to the
bottled waters the charm of the original effervescence, it was
necessary to re-charge them with carbon dioxide; and this
was done at first in the manner usually employed in bottling
seltzer, and some other gassed beverages. This process,
briefly, consisted in the preparation of carbon dioxide from
sulphuric acid and marble-dust, and the absorption of it by
the mineral water by agitation under pressure in strong iron
cylinders. Then it was bottled in the common way, or
sometimes was enriched by the addition of ginger syrup and
flavorings, and put up as ginger-ale, or as the Manitou Mineral
Water Company felicitously called it, "ginger champagne."
About the year 1889 the desirability and feasibility of using
the natural gas from the springs to re-charge the mineral
water and champagne, was suggested to the Company, and
this plan, proposed by the writer and carried out under his
supervision, was soon put into practical operation.
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 15
It may be of interest to discuss the origin of this natural
gas, and then to describe the means by which it is made to
again impregnate the mineral water taken from the springs.
In seeking to trace the sources of this abundant supply
of natural gas, it will be helpful to consider certain of the
prominent geological and topographical features of the dis¬
trict iu which the springs occur. Manitou lies in a mountain
gulch or valley at the base of Pike's Peak, and just at the
entrance to the Ute Pass. In fact the valley is but the
eroded and widened outlet of the Pass—itself a narrow water-
carved channel through which the drainage of an area some
seventy-five to one hundred square miles in extent finds its
way to the eastern base of the mountains. The stream which
drains this tract obtained the name "Fontaine qui Bouille"
from the bubbling or boiling springs on its banks at Manitou.
On the south and west of the picturesque little city rise the
granite slopes of Pike's Peak, while to the north are piled up
the huge masses of stratified rock which flank the other side
of the valley. Thus Manitou lies at the junction of the old
archaean rocks, with more recent sedimentary formations.
Just west of Manitou, however, the limestone beds are found
for a short distance on both sides of the Ute Pass. The
archaean rocks at Manitou consist almost exclusively of
highly feldspathic red granite which disintegrates very readily
under atmospheric agencies. Further up the Pass are found
patches of syenitic gray granites containing soda feldspars.
There are no igneus rocks in this neighborhood save a few
narrow dikes, and on the south slope of Pike's Peak, about
two miles from the summit, one exposure of phonolite, but
not many miles distant at Cripple Creek, large areas of erup¬
tive rocks are exposed to view. A number of rock slips or
faults in the granite are to be seen in the neighborhood of
the Peak.
At Manitou *and to the northwest, only the paleozoic
series of sedimentary beds are exposed, e. g. silurian, carbon¬
iferous and juratriasic, and these are mainly represented by
limestones and sandstones. The granite slopes of the Front
Range, which extend in a generally north and south line, are
16
COLOEADO COLLEGE STUDIES.
depressed in a sort of recess or bay at Manitou and to the
northward, and these older sedimentary beds rest npon them,
and outcrop in their regular order, showing themselves for
several miles up the Ute Pass. To the northwest of the Ute
Pass and continuing in the same direction, extends a long,
narrow strip of the same series of sedimentary formations.
Probably these two areas were once continuous ^ind have
since been separated by erosion. At the lower end of the
latter, or Manitou Park, area, a prominent fault having a slip
of three or four hundred feet follows the junction of the
granite with the southern side of the sedimentary beds,* and
at Manitou, near the Rainbow Falls, there is also a fault with
a slip of twenty feet or more, which takes about the same
direction. It is probable that these faults form a continuous
fissure over the short interval between the two areas, and
quite possible that the infiuence of this fissure or slip de¬
termined the course of the stream which cut the Ute Pass
so deeply in the rocks. From the prevailingly slight dip of
the strata it is probable that the sedimentary beds at Manitou
do not extend to very great depths beneath the surface, and
the same observation applies also to those at Manitou Park.
At Manitou the general inclination of the beds is to the
southeast, though there are several folds which steeply incline
some portions of them just west of the city. There are, how¬
ever, in the vicinity of the springs at Manitou, a couple of
small flexures of strata, indicated mainly by rock exposures
on the north side of the valley which should be noticed.
They run transversely across the valley, and may be described
as being only more abrupt or sudden inclinations of the
southeastwardly dipping strata. It is at the crests of these
low folds that the springs appear. The oldest limestones are
very silicious, and in places just west of Manitou where they
are shattered and bent, often contain cavities filled with
argillaceous red oxide of iron. The " Caverns" so much
visited at Manitou occur in the limestone, and show the re¬
sults of a former great chemical activity at that point. When
first discovered, very considerable beds of the same ferrugin-
* See the Pike's Peak Folio, edition of 1892, U. S. Geological Survey.
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 17
ous matter covered the floors and filled some of the passage¬
ways of the caves. The springs are found at three points in
the valley, and these places are at the apices of a triangle
roughly equilateral. The group including the Navajo, Mani-
tou, Cheyenne and Shoshone, which lies in the center of the
town, and forms the eastern end of the triangle, has the
largest flow of water and gas. The eastern of the two trans¬
verse rock flexures occurs at this point. West of this group
the valley widens and divides, and the Ute Iron spring is
found in Engleman's Canon, a short distance above its mouth,
and almost in the granite. The third position, that of the
Hiawatha group, is in the general line of the valley, near
the limestone rocks, and not far below the entrance to
the Ute Pass. It is said by old residents that the largest
spring was not many years ago found at this place, but that
it was deeply covered and quite obliterated by deposits of
gravel brought down the Pass during a severe freshet. In the
neighborhood of each group of springs the gravel and wash
has been cemented by a tufaceous substance'deposited from
the waters and called locally "soda-rock." The Navajo group
and the Ute Iron spring are near to the line of contact of the
granite with the sedimentary beds; the Hiawatha group is
near the line of the Ute Pass fault. In all cases the springs
lie close to the streams, and in the creek bed near some of
them, numerous small vents are shown by rising bubbles of
gas.
The rain and snow descending upon the earth bring with
them matters washed from the air, and after reaching the
ground the waters dissolve portions of all the soil and rocks
over which and through which they make their way. It is
therefore natural to seek in the waters of these springs for
evidence concerning the rocks they have traversed, and thus,
if possible, trace nearer to its origin the accompanying gas.
The following aiJklyses of water from several of the more im¬
portant springs were made by Prof. Elwyn Waller, Ph. D., of
New York, from samples taken from the springs by the writer
in the summer of 1891. These results have been confirmed
by analyses made in the laboratories of Colorado College on
18 COLORADO COLLEGE STUDIES.
several different occasionB, when the samples were also taken
in the summer season.
IN PARTS PER 100,000 OF WATER
CONSTITUENTS POUND.
Navajo
Manitou
Ute Iron
spring.
spring.
spring.
53.959
52.176
41.370
Potassium
7.650
8.219
6.018
Lithium
0.201
0.230
O.OS)
Calcium
47.560
47.382
21.747
Magnesium
7.859
8.173
3.939
0.032
0.028
0.326
Aluminium
0.092
0.069
0.140
Chlorine
24.625
24.781
17.520
Sulphuric anhydride
18.410
18.232
20.703
Carbon dioxide
195.366
193.545
104.159
4.230
4.280
6.200
Oxygen in bases
39.296
38.910
23.203
Water in bicarbonates
39.962
39.588
21.305
Totals
439.243
435.613
266.665
Totals in grains per gallon
256.157
254.041
155.514
The elements found in the Hiawatha group of springs are
the same as those shown to be in the other groups.
Below are tabulated the salts contained in the waters,
calculated according to the conventional methods, from the
preceding figures.
IN PARTS PER 100,000 OP WATER.
SALTS PROBABLY PRESENT.
.
Navajo
Manitou
Ute Iron
spring.
spring.
spring.
Sodium chloride
40.803
41.061
29.030
Potassium sulphate
17.067
18.335
13.425
Sodium sulphate
18.749
17.397
25.792
.Sodium bicarbonate.
115.804
110.518
78.540
Lithium bicarbonate
1.946
2.235
0.336
Calcium bicarbonate
192.613
191.900
88.076
Magnesium bicarbonate
47.812
49.719
23.965
Iron oxide (ferric)
0.046
0.040
1.037*
Alumina
0.174
0.130
0.264
Silica
4.230
4.280
6.200
Totals
439.244
435.615
266.665
♦Ferrous bicarbonate.
ORIGIN AND USE OP NATURAL GAS AT MANITOU. 19
The temperature of the Navajo and Manitou springs was
tested on two or three occasions and found to be about 15° C.
In July, 1894, it was also the same. On December 31, 1894,
after five days of quite cold weather (the thermometer regis¬
tering nightly —18° C. or lower), and again on January 10,
1895, after a continuous period of cold weather, the tempera¬
ture of several of the springs was tested, and samples of water
from some of them also taken. The temperatures observed,
and the residues obtained by evaporation of the samples of
water, are given in the subjoined table. The residues are
given in grains per gallon.
DATE OP TEST.
NAME OP SPRING.
Navajo.
Manitou.
1
Ute Iron.
Ute Chief.
Hiawatha.
Hiawatha
No. 2.
Dec. 31 •
Jan. 10 '
Temperatures C.
14°.5+
178.40
14°.5t
177.57
14°. 5
12°.0
*109.52
7°.0
113.66
ir.o
tll°.5t
119.16
tl2°.0
117.86
11°.5-
51.10
11°. 0
50.85
Temperatures C.
14°.5-
176.12
* A small precipitate of an iron compound had formed and settled before the
analysis was begun—the result is therefore a little low.
fThe Hiawatha spring is covered with an iron cap, cemented to the curbing,
and the water tested on December 31 was obtained from the overflow and caught in
a gallon measure, and as the vessel was cold the temperature obtained was probably
too low. On January 10 the thermometer was held In the water escaping from the
overflow pipe. This overflow pipe is buried under four or Ave feet of gravel and is
some twenty or thirty feet in length.
The gas emitted from all of these springs is pure carbon-
dioxide. The quantity given off from the different springs
is quite unlike, varying from a few hundred cubic centi¬
metres per hour to three or four hundred litres or more in
the Navajo and Cheyenne. The flow from each spring is,
generally, during the greater part of the year, very uniform
in quantity, though it is said that after heavy rains or when
snow is melting the quantity given off is increased. This
increase may arise from greater hydrostatic pressure of the
swollen stream upon small vents in the creek bed and unseen
vents along the banks near the springs, thus forcing more gas
20
COLOEADO COLLEGE STUDIES.
through the main channel. The foremen of the bottling de¬
partment of the Manitou Mineral Water Company's plant
report that a diminution of the flow of both water and gas
occurs in the Navajo group of springs during the coldest
weather of winter. It is to be observed that the spring
waters never become turbid or roily after storms and freshets,
although the surface streams are especially affected in this
way. One of the springs of the Hiawatha group (the covered
one) is slightly turbid from insoluble salts which probably
result from reactions occuring in close proximity to the
spring. Some of the spring waters on standing, quickly de¬
posit a precipitate, while others, even from the same group
of springs, remain clear for a much longer period. Con¬
siderable pressure is developed by the escaping gas when the
waters are immediately bottled and hermetically sealed as
soon as drawn from the springs. Large glass vessels are apt
to be burst by the pressure of gas if filled quite full before
sealing.
The surface waters in the district under examination con¬
tain relatively very small quantities of mineral matters in
solution; nor are there springs or pools in the area which
drains through the Ute Pass that are known to be highly
mineralized. In the upper part of the Pass between Cascade
and Green Mountain Falls there are springs and small
marshy spots where a notable quantity of hydrated sesqui-
oxide of iron is liberated from ferruginous waters, and these
waters come apparently from the granites on the south side
of the Pass. No thermal springs are found in this vicinity
other than those at Manitou.
Taking the three analyses given above as a basis of dis¬
cussion, and using also the later results as data, certain points
among the many possible inferences will here be noted.
1. All the springs hold the same salts in solution, a fact
which seems to point to a common origin.
2. The waters of the Navajo and Manitou springs are almost
identical in mineral contents, while the Ute Iron spring
contains a much smaller quantity of dissolved salts.
There is also a difference in the weight of the residues
OBIGIN AND USE OF NATURAL GAS AT MANITOU. 21
from the Hiawatha springs. It is very probable that
percolating waters from the streams or from local
seepage channels, make their way into the springs—
such influx being greater in some springs and smaller
in others. In the Ute Iron spring calcium and mag¬
nesium are low, and silica, chlorine, iron, sulphuric-
anhydride, soda and potash relatively high. The prox¬
imity of this spring to the silicate rocks on the south,
and to the very broken silicious silurian limestone and
Cambrian quartzites on the north and west, suggest
reasons for a possible change in this spring water, on
the supposition that its main source is the same as
that yielding the waters of the other groups.
3. The presence of so large quantities of the bicarbonates of
calcium and magnesium points to a prolonged contact
of the waters with the limestones.
4. The almost total absence of iron salts indicates either a
source quite free from ferruginous minerals, or more
probably the oxidation of dissolved iron and its
previous precipitation as hydrated sesquioxide by the
carbonated alkaline matters with which it comes in
contact as the waters move toward the springs.
5. The high percentage of chlorides may be derived from
the silurian rocks or with less probability from the
more distant juratriasic beds, since no saline deposits
in them are known in this vicinity.
6. The large percentage of sodium bicarbonate probably in¬
dicates an origin among silicate rocks, whence the soda
(and potash) may come as carbonates formed by the
decomposition of the rocks by atmospheric waters con¬
taining carbonic acid, or as alkaline silicates, which
react upon the limestones (calcium carbonate) before
reaching the surface.
7. The sulphatfes may come from unseen gypsum beds such
as are found two or three miles away, and lower down
the Fountain creek, but it is more probable that they
come in greater part at least from the oxidation of
sulphides in granites, igneus rocks or even sedimentary
22
COLOEADO COLLEGE STUDIES.
beds. The oxidation of ferrous sulphate, such as was
described as occurring in the Ute Pass, gives rise to
sulphuric acid, and by subsequent reaction with car¬
bonates to sulphates of the alkalies. The ferruginous
deposits in the broken silurian limestone indicate such
a reaction.
8. The concentration of the solutions—that is, the large
quantity of mineral matters contained in the spring
waters, comes evidently from prolonged contact with
rocks, such as would arise from percolation, and prob¬
ably also from an increased solvent power of the water,
due to heat or pressure, or both combined.
9. The difference in temperature of the several springs is
remarkable as showing that either the waters come
from different sources, or if coming from the same
source have been cooled in an unequal degree by passing
through diverse strata, or through the influx of cooler
foreign waters. It was assumed under (2) above that
the most probable view was that the same water is made
to vary its content of dissolved mineral matters by the
admixture of other waters; and the variation in tem¬
perature between the springs will be found on inspec¬
tion of the table above to be in striking harmony with
this supposition. The temperature in general is lower
when the mineral content is lower, but it should be
remembered that the inflowing foreign waters may also
pass through strata so deeply buried as to be much
warmer than mere surface waters.
10. The variation of the springs between summer and winter,
in their contents of mineral matters dissolved, in the
quantity of water flowing from them, and in the volume
of gas yielded, together with the remarkable uniformity
of temperature throughout the year in some of them,
are evidently significant phenomena. The causes pro¬
ducing them will be discussed in a subsequent para¬
graph.
Before proceeding to deduce from the foregoing state¬
ments a theory of the derivation of the carbon dioxide of the
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 23
Manitou springs, it may be helpful to recall to mind some of
the explanations most frequently given for the production of
natural gas in large quantities beneath the surface of the
ground. First, then, may be mentioned the slow, natural
distillation of the buried or fossil organic matters that are
found in many strata, notably in the shales. The volatile
products evolved in this manner contain large quantities of
marsh-gas and similar combinations of carbon and hydrogen,
with but little carbon dioxide. The wide distribution of gas
wells over the country attests a very general chemical action
of this sort yielding combustible gases. At Colorado City,
three miles distant from the Manitou springs, a small flow of
combustible gas has been obtained from the two wells already
bored. A Second cause, obviously a true one where the proper
conditions exist, is found in the heat of lavas or igneus rocks
where they come directly in contact with limestones. It may
be doubted whether much gas is ever produced by actual rise
of temperature in this way without the aid of moisture, but
unquestionably superheated waters carrying dissolved mineral
matters and accompanied by vapors and gases produced by
such igneus rocks, would effect the liberation of this gas.
Thirdly, limestones deeply buried under later deposits of
rock will suffer an increase of temperature due to the rise of
isogeotherms, and heated mineralized waters will then bring
about chemical reactions with the limestones. Simple rise
of temperature alone will not suffice in such enclosed zones
to liberate the carbon dioxide, though with the aid of moisture
it may metamorphose the limestones to marble. A last cause
to be noticed here is the chemical decomposition of lime¬
stones effected, with or without high heat, by acid waters or
by salts which react with the carbonates of lime and mag¬
nesia, forming a new series of salts and setting free carbonic
acid gas. This last cause has been in part anticipated in the
two preceding theories of the derivation of the gas.
As the development of a theory of the formation of car¬
bon dioxide probably turns in no small degree upon the
action of substances in solution derived from the rocks, it is
appropriate here to consider some of the results of investiga-
24
COLOBADO COLLEGE STUDIES.
tion along this line. The disintegration of surface rocks by
atmosxjheric agencies is very apparent to the eye, and the
products of this resolution of the rocks have been the sub¬
ject of careful study. Carbonic acid from the atmosphere,
or that derived from the oxidation of decaying organic mat¬
ters in the soil, plays a very important part in the disintegra¬
tion of silicate as well as of carbonate rocks. It produces in
the former class carbonates of the alkalies and alkaline earths,
and these salts are carried away along with some silica and
metallic carbonates, etc., in the percolating waters. It is
believed that all rocks, at least to very great depths, are per¬
meated with water which has made its way from the surface
downward, and which exerts an action like that shown on
rocks near the surface of the ground. As these meteoric
waters descend they gradually lose the more active elements,
dissolved oxygen and carbonic acid, with which they began
their journey—being exhausted in short distances when they
percolate slowly through the rocks, and carrying them to
great depths when they pass through porous or shattered
rocks, especially when they find channels or fissures in which
to flow; but as the waters reach more deeply buried zones a
new resolvent power and chemical activity is developed in
greater and greater degree by the increasing heat and pressure
to which they are subjected. Under the influence of these
stimuli the metamorphism of rocks proceeds at a vastly in¬
creased rate, kaolinization, solution, chemical combination
and crystallization working a silent, ceaseless change in
many kinds of deeply buried formations. Evidence of this
heightened action of heated waters is afforded to us in the
hot springs of all countries; as a rule, waters which issue
from the earth at high temperatures bring with them excessive
quantities of dissolved mineral matters. The modern theories
of the filling of fissure veins is largely based upon the greater
solubility of silicious and calcareous compounds, metallic
sulphides and other vein matter, in the heated waters at the
deeper parts of the earth's crust to which such crevices
extend, or to waters heated by bodies of igneus rocks in
process of cooling; although of course at any depth, small or
great, the solvent action of water takes place, and solution
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 25
may proceed more rapidly in one kind of rock than in another.
The application to be made of the foregoing observations
depends upon the fact that" waters thus highly charged with
mineral matterg in rock fissures would be well adapted to
produce reactions upon limestones if they should chance to
come in contact with them. It should not escape notice that
the flow of gas at Manitou takes place within a very limited
area, and that no other similar springs are found in this im¬
mediate region. It is a very local phenomenon. Whatever
the causes which give rise to the gas, they can have no gen¬
eral application to the similar series of rocks extending for
many miles along the mountain slopes, else the evidences of
their action would be more widely distributed. Hence some
local cause is to be sought at Manitou as the producer of the
Sas.
Having thus examined the situation at Manitou and briefly
reviewed some theories of the evolution of carbonic acid gas
from the earth, it is now possible to more definitely assign a
reasonable cause and source of the flow of gas in question.
It seems to be generally agreed that the carbonates formed
through the decomposition of silicate rocks by atmospheric
waters will not by any known reactions in those rocks alone
account for a large flow of gas. Also the evolution of carbon
dioxide by the slow, natural distillation of carbonaceous mat¬
ters deeply buried in strata, is an explanation not applicable
to the present case, because of the great purity of the Manitou
gas. The disengagement of the gas from limestones sub¬
jected to heat from rising isogeotherms appears improbable
because the strata at Manitou seems not to be very deeply
buried, and because the salts found in the water of the springs
point to another class of rocks as a source, and also because
the springs are confined to so limited an area.
The presence of masses of igneus rocks near the limestones
may be considered a possible explanation of the phenomenon,
since though no*such eruptions outcrop near Manitou, there
may yet be intrusive masses of them buried more or less
deeply beneath the gravel or sedimentary beds. The waters
of the springs would probably have a much higher tempera¬
ture than they now possess if masses of igneus rock retaining
26
COLORADO COLLEGE STUDIES.
still sufficient heat to cause the water to dissolve its large
percentage of mineral matter, occurred in this immediate
neighborhood. Altogether, in the absence of some positive
evidence of the presence of such heated rocks this explana¬
tion must be quite doubtful.
It remains then to discuss the probability of the formation
of this gas by chemical reaction of dissolved substances in a
flow of water which reaches the limestones of Manitou, and
to examine whether there are at hand sources whence this
saline solution might reasonably be expected to come. This
explanation differs from the preceding one mainly in that the
source of the reacting salts is more remote. Is there such a
source of active chemical solutions present at Manitou, and
if that be asserted, what evidence can be adduced in support
of a theory of this sort? It must be admitted that positive
proof is not now attainable, but there are some considera¬
tions which may be urged in favor of such a theory.
Reference has already been made to the faults and rock-
slips at Manitou, and to the probability of the presence of an
extensive and profound rock-fissure extending from Manitou
continuously along the general line of the Ute Pass up into
Manitou Park. In view of the presence of an extensive out¬
flow of igneus rocks not many miles distant at Cripple Creek,
and of an outcrop of phonolite nearer still on the south side
of Pike's Peak, it is altogether likely that a deep fissure such
as that at Manitou, if not in some way connected with those
disturbances and the loss of interior liquid matter under this
region, yet penetrates to depths strongly affected by these
heated zones. If a fissure occurs at Manitou which penetrates
the earth's crust sufficiently to reach highly heated rocks, the
natural action observed in fissure-vein filling will be very
actively induced, and highly mineralized solutions will result
as before explained. And if further the fissure at Manitou
extends to Manitou Park or communicates with fissures of
the Cripple Creek district or with those in some other
elevated region, the waters which everywhere find exit in
such rock crevices, would, in seeking their level, according to
physical laws, naturally emerge at the lower point where the
ORIGIN AND USE OP NATURAL GAS AT MANITOU. 27
springs are found. Heated waters, or waters even slightly
heated, on coming into contact with the superincumbent lime¬
stones of Manitou would promptly set up chemical reactions
caused by the presence of soluble matters such as the silicates
of the alkalies and other metals, silicic acid, sulphides, sul¬
phates, etc., derived from the heated rocks. The reactions
which would take place need only be generally indicated here
since they are not peculiar to this theory. Alkaline silicates
would change to carbonates; alkaline bicarbonates, in so far
as these reactions were possible, to sulphates, or,—if chlorine
combinations of lime and magnesia exist in the silurian lime¬
stone—to chlorides, in both cases—at even a very moderately
elevated temperature—with the evolution of carbon dioxide;
iron salts would first become carbonates and then peroxidize,
setting carbon dioxide free and forming a ferruginous pre¬
cipitate. If the waters were only slightly hot, silicic acid
would form insoluble calcium silicate with the liberation of
carbon dioxide. In the case of hot waters the basic carbonates
of magnesia and probably also of calcium would be formed
instead of normal or acid salts by reactions of the salts of
the alkalies, etc. These, with other known and possible re¬
actions, account for the generation of the gas. The salts con¬
tained in the spring waters may also be fairly explained in
part by these reactions, and in part by reactions produced,
and other salts introduced, through the accession of seepage
waters in the passage to the springs. The concentration of
solutions, or the high percentage of salts in the water, is well
explained by this derivation. A large fissure like the one
assumed to exist at Manitou must receive meteoric waters by
seepage along its whole course, and such additions bring with
them each their small quantity of dissolved salts. The waters
which emerge from the fissure at or above Manitou must
also be considerably changed in mineral contents by the
accession of seepage waters from the local rocks, and thesp
changes are prot)ably greater at some points than at others.
The difference in temperature between the various springs,
and also their difference in mineral matters dissolved in the
water, may thus be credibly explained. The surface waters
do not readily make their way through the "soda-rock" into
28
COLORADO COLLEGE STUDIES.
the springs and hence the springs do not become roily, and
the temperature of the water remains quite constant, retain¬
ing still enough heat to be designated as "thermal" in the
U. S. Government Reports.
The coincidence between the diminution of the salts and
that of the water and gas during the coldest winter months,
probably arises in this manner. The feeders of this fissure-
flow are in large part the seams and cleavage cracks in the
rocks adjacent to the main fault or its branches, and they in
turn derive their supply from the surface waters which per¬
colate downward. In the very cold weather the seepage
waters—as is well known in mining regions at high eleva¬
tions— are greatly diminished, being held in check by frost,
so that the supply is lessened in the main fault. In like
manner the slopes of the Ute Pass and the neighboring hills
which may be supposed to furnish the seepage waters of the
sedimentary beds at Manitou are restraining (by frost) their
quota of the supply for the springs. Especially would this
be true if, as appears probable, the more elevated and com¬
paratively shaded south side of the Pass furnishes the bulk
of the seepage waters which make their way to the springs.
Under these conditions the temperature of the springs would
not generally greatly vary in summer or winter, since the
colder surface waters of the latter season which mingle with
the decreased fissure-waters would also be much diminished
in volume. With the decrease in water would come a de¬
crease in salts, and so also of the gas produced by the re¬
actions previously outlined.
The salts coming from the assumed fissure beneath the
limestones naturally tend to follow the seams and bedding
planes of the stratified rocks and thus to make their way
down the easterly slopes without coming to the surface. The
resistance to this flow resulting from friction and perhaps
from sharp folds and faults east of Manitou, causes the waters
to force an exit through the broken and folded strata at the
western side of the city. The two small flexes of surface rock
before mentioned appear to give in their crevices the oppor¬
tunity for a final escape to the surface of the water and gas.
OEIGIN AND USE OF NATURAL GAS AT MANITOU. 29
All the circumstances, therefore, connected with the posi¬
tion and flow of the springs, and the mineral contents of the
water, etc., etc., seem to be consistent with, if they do not
favor this explanation.
Briefly, then, the theory advanced of the origin of the
natural gas at Manitou may thus be summarized: Water
percolating through silicate rocks and becoming highly min¬
eralized under favorable conditions of temperature and pres¬
sure, makes its way through cracks and profound rock-fissures
by the action of gravity and the ascensional power imparted
by heat, to the limestones west and north of Manitou. It is
here increased in volume and in dissolved salts by the numer¬
ous additions of seepage waters from the local rocks, and also
lowered in temperature at the points where these influxes occur.
By chemical reactions some of the dissolved salts are changed,
and the carbon dioxide originally held (almost entirely) by
the limestones is liberated from that combination but dis¬
solved in the water on account of the great hydrostatic pres¬
sure. As the waters rise through the irregular channels
enlarged from cracks and seams, the pressure decreases, and
more and more of the dissolved gas escapes from the water,
until at last when the surface is reached at the various springs
the gas emerges with the rythmic flow due to the irregulari¬
ties in the channels of exit.
Of the many temptations to comparisons and generaliza¬
tions growing out of his study upon the origin of the natural
gas at Manitou, the writer yields to the two following: (1) The
caverns at Manitou mark the scene of a former considerable
chemical activity, possibly induced by the same causes now
at work in the lower strata in the manner mentioned above.
If the theory advanced in this paper is true, caverns of like
kind may now be in process of excavation which will in time
rival or eclipse those so much admired in the now drained
and fragmentary parts of strata on the west side of Williams'
canon. (2) The data in the hands of the writer concerning
the carbonated mineral springs of other localities are too
meagre to permit of any very general comparisons or deduc¬
tions, but it would appear from published descriptions that
30
COLORADO COLLEGE STUDIES.
in some notable instances, at least, the flow of carbon dioxide,
just as at Manitou, occurs where there are no igneus rocks,
but at points where the older rocks have been faulted or
fissured below overlying limestones. A case in illustration
occurs at the Saratoga springs in New York. The silurian
limestone is there faulted by a fissure which extends down
into the archsean rocks below, and no other visible canse ap¬
pears for the generation of the gas. Also the conditions of
the Canon City, Colo., carbonated springs seem, from an ex¬
amination of the geological maps, to be very similar to those
at Manitou—but the writer has no positive knowledge as to
whether or not the rock fissures in that region extend to the
vicinity of the springs as is the case at Manitou. The pub¬
lished analyses of the water from the springs at Canon City
show that in respect of both the kinds of salts and the
quantity of them present, they very closely resemble the
springs, at Manitou.
The second part of this paper concerns the use made by
the Manitou Mineral Water Co., of the natural gas which
comes from the springs. A description of the steps taken
and the apparatus devised to accomplish this end may be of
interest. In the early days the Navajo group of springs
bubbled and fizzled in a peaty morass, and could be approached
with difficulty. The Navajo spring which gave the most
gas and water was then curbed with cement and stone and
the swamp filled up with earth. From this spring was drawn
the water put up by the Company in 1889, at the time the
proposition was made to use the escaping gas to recharge the
bottled water. In the accomplishment of this plan three
problems required solution, namely: (1) to ascertain the
quantity of gas available for use: (2) to devise means for
catching and storing the gas: (B) to obtain a gas-pump which
would continuously and practically compress the gas to the
degree obtained in the old gas-generators, i. e. some 60 to 80
lbs. per square inch.
The measurement of the gas was effected as follows: A
large tin funnel, stiffened at the wide opening with heavy
wire, and made very short from large to small end, was sunk
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 31
mouth downward under the water of the spring as deeply as
possible. The mouth of the funnel was bent after several
trials to conform to the irregularities of the spring, and the
funnel when thus fitted was held in place by wooden supports,
because pressed upward with much force by the rising gas.
A large bell-glass of a capacity of 7 or 8 litres was used to
make the measurement. This bell-glass when filled with
water by immersion in the spring was held mouth downward
over the small opening of the funnel whence the gas now
escaped, and as the gas entered it the water was displaced.
The bell-glass was gradually raised out of the water as the
gas accumulated, until when it was full of gas the mouth just
dipped beneath the surface of the water. In this way the gas
was measured at the then prevailing atmospheric pressure.
Owing to the very rapid fiow of the gas, the time required to
fill the bell-glass could not be very accurately determined,
though by repeating the experiment many times and taking
an average of the time records, the number of seconds re¬
quired to fill it was ascertained with sufficient accuracy for
practical purposes. The quantity of gas evolved daily was
now easily computed, provided the fiow was constant as
observation had seemed to indicate. With these figures it
was possible to calculate the number of bottles of water that
could be recharged with this natural gas per diem. Roughly
speaking, water will absorb its own volume of carbon dioxide
whatever be the pressure to which the water and gas are
subjected. Assuming a pressure at which the company would
bottle the waters, the reduction in volume of the gas was
VT)
obtained by the use of the formula The rise of tem-
P .
perature, due to compression, could practically be neglected
since the water sufficiently cooled the gas. The number of
bottles which could be filled from this supply of gassed water
was ^ if A represented the capacity of each bottle. Thus
the Company was assured that the supply would be much
more than sufficient for the then daily output of the works.
The second problem involving the construction of appa¬
ratus for catching and storing the gas was somewhat more
82
COLORADO COLLEGE STUDIES.
troublesoine. The conditions were (1) that the waters of the
spring, which were used for bottling, must be preserved from
contamination by metallic salts; (2) that the gas must be
forced by its own pressure to an appropriate gas-holder;
(8) that the spring must be accessible for cleaning and ad¬
justment of the overflow pipes which carry the water to the
bottling works. Another point which had some influence in
determining the character of the apparatus to be used, was
the wish of the Company to have all parts of it open to in¬
spection by visitors to the works,—a policy the wisdom of
which has been amply justified by subsequent experience.
To meet these requirements it was decided to immerse a bell-
shaped vessel in the spring to catch the gas. From this bell
the gas could be carried in pipes to the works, two or three
hundred feet distant. In order to give the gas sufficient
pressure to force it through the conducting pipe, and send it
into a receiver or gas-holder, it would be necessary to depress
the bell in the spring water sufficiently to allow for the dif¬
ference in level between the surface of the water on the out¬
side and that of the water within. At the gas-holder this
conducting pipe would have to dip into water several inches
in order to make a water-seal connection, to prevent loss of
gas in case of accident to the pipe or bell, and in the gas¬
holder itself, a slight pressure would be needed to send the
gas to the pumps. In preparation for the reception of this
bell the spring was cleared out and somewhat deepened, and
upon the rocky bottom, a short distance above the vents
whence issue the gas and water, a shelf of cement, circular in
plan and about six inches wide, was built within the inclosing
walls of the spring, which were also made cylindrical. On
this shelf the bottom of the bell was to rest. An incident in
the work of deepening the spring and constructing the shelf
and walls is worthy of passing note. The volume of gas was
so great that workmen could not remain a moment in the
excavation without apparatus to supply fresh air. This was
provided by the use of a dentist's gas-inhaler connected with
a piece of common garden hose reaching above the curb of the
spring. Even with this inhaler it was necessary to stop the
nostrils of the men with plugs to keep out the gas. When,
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 33
as often happened, one of these nasal stoppers become dis¬
placed, the workman would precipitately bolt for the surface
with a shout of pain from the sharp sting of the gas in the
nose and air-passages. Tears would flow from the eyes of
those engaged in working at the bottom of the spring.
The material of which to make the bell was important
from the fact that the water of the spring must be used for
bottling. Iron rust would destroy the clearness of the water;
lead, copper and zinc would add poisonous salts, which,
although present in very minute quantities, would yet cause
distrust in the minds of users of the water; silver was the
ideal metal, but its then high value barred its use. Block-tin
was accepted, though the difficulties in the way of its use
were quite serious. The form of the bell adopted is shown
in sectional elevation and plan in the annexed plate. It was
built by The Hartt Manufacturing Co., of Chicago, after plans
of the writer. The sheets of block-tin (No. 12 American wire-
gauge thickness) were held in place and stiffened by a skele¬
ton frame made of heavy iron wire encased in tin pipes. The
frame as thus made has been found in subsequent use to be
too light, and the bell requires the most careful handling to
prevent distortion and cracking; otherwise it has well fulfilled
its purpose, and now (Jan. 1895) is almost as good as when
first set in 1890. In order to show to the many visitors the
flow of gas in the spring, the top of the bell was made of
plate-glass, and just below the glass hung an electric incan¬
descent light. The bell is held firmly in place by iron stays
fastened to the curbing.*
The temperature of the springs (about 60° Fahr.) is so
high that the gas is loaded with moisture, and condensation
in the conducting pipe results, especially in cold weather.
In order to prevent a stoppage of the pipe a drip-trap (see
plate) made of gas pipe was inserted at the lowest point in
the line, and an escape for the accumulating water provided.
■
♦ Before closiDir the description of apparatus for catching the gas, it should be
added that at one of the Hiawatha springs the owners have caught the gas by the
use of an iron dome cemented upon the curbing of the spring. There is no way to
get into the spring to repair pipes, etc., except by breaking the cement sealing. It
would appear to be a wise measure to have provided a manhole with a movable
cover in this dome to obviate that ditliculty. A couple of iron bells placed in other
' springs are rusting rapidly and render the waters turbid.
34
COLORADO COLLEGE STUDIES.
The conducting pipe was buried under ground to prevent
freezing.
The gas-holder is designed to hold twenty-four hours
yield of gas from the springs. It contains no strikingly novel
features. The bell or holder is supported by three chains
which run over pulleys attached to heavy timbers set for this
purpose in the Company's building, and bucket weights are
loaded to give the required pressure to send the gas to the
carbonating apparatus. The holder dips in water contained in
a cemented cistern which can be conveniently drained and
cleaned. A large manhole in the top of the holder provides
access to the cistern and to the enclosed pipes. An electric
incandescent lamp suspended just beneath the arched top of
the holder permits inspection of the pipes for the ingress
and exit of the gas; and for this purpose also a number of
small glass plates are cemented in a perpendicular line
on one side of the holder at intervals of about two feet.
The pipe which brings the gas from the spring, and that
which leads it to the carbonators, and that which provides
for the escape of an excess of gas, rise from the cemented
bottom of the cistern and are supported upon an iron
tripod, as shown in the accompanying plate. The pipe
for the entrance of the gas curves in the form of a goose¬
neck and dips under the water some five or six inches, to
effect a water seal against back-flow. The overflow pipe is
capped by a metal bell which dips into the water of the cis¬
tern so long as the holder is not yet full of gas, but when the
holder is full the cap of the overflow pipe is raised from the
water and gas is allowed to escape. This cap or gas-trap
(see plate) is connected by a metal chain with the top of the
holder, and is therefore raised from the water when the
holder rises above a certain height. This apparatus has
sometimes caused trouble by the kinking of the chain con¬
necting the holder with the metal cap. The chain should be
made of small links so that it may readily coil in the little
dish at the top of the metal cap, and uncoil again without
kinks. A small rod suspended from the roof of the holder,
which would lift the cap by an arm, would perhaps obviate
any difficulty of this sort.
ORIGIN AND USE OF NATURAL GAS AT MANITOU. 35
The problem of the compression of the gas in order to
re-charge the water with it, was one of vexation and difficulty.
The plan at first attempted was to pump the gas into the old
iron gas-generator, whence it could be drawn and used in the
same manner as was the artificially-made gas. It was not
successful, because the pump bought for the company would
not continuously, nor even for an hour, compress the gas
without destroying the packing of the piston-head. The heat
developed by the compression and the strain upon them, in
a few moments reduced rubber washers to shreds, and leather
ones lasted but little longer. About this time the writer,
while in New York city, heard of a new form of carbonating
apparatus invented by the Wittemann Brothers. Three of
these machines were then employed in practical work, and
an inspection of the one operating in New York left no room
for doubt as to their merit. The principle of the machine
was one to tickle the fancy of a man of science. The gas was
pumped into a small cylinder of glass or metal and the water
to be carbonated was also pumped into the same chamber by
the action of the same piston-rod. The water entered the
cylinder of compressed gas through a smaller interior cylin¬
der pierced by a great number of very small holes. The
water was thus sprayed through the compressed gas, and was
therefore most advantageously disposed for quickly absorbing
the gas; in fact the absorption was instantaneous. The
carbonated water now flowed to a balanced reservoir which
operated to shut off the supply of gas or water or both, if
necessary, to maintain a proper pressure and a constant
supply for the bottling tables with which it was connected.
Thus the machine was automatic and continuous-working in
its operation. The success attending the use of this pump
induced the Company to put in several larger machines of
the same sort as their business increased. As a result of the
experiences in the operation of the apparatus described in
this part of the paper, several slight modiflcations might be
made if new ones were to be constructed, but it is fair to
observe that in practical working the results have been on
the whole very satisfactory.
The writer wishes to acknowledge the courtesy of the
Manitou Mineral Water Company in assenting to the publi¬
cation of many details pertaining to the successful operation
of their business.
Plan of Tripod andPipes
Sectional Elevation Elevation oi Tripod and
on AJB. Pipes,
of Gas-Sell.
Scale. ;i£ = 1 .
HERPETOLOGICAL NOTES FROM KANSAS AND TEXAS.
BY F. W. CKAGIN.
Terrapene ornata, Ag., var. nov. cimarronensis.—I would
propose this name for'what appears to be merely a color
variety of T. ornata in which the ordinarily yellow parts on
the limbs and neck are replaced by bright red. This variety,
with which I have been acquainted for some ten years, is
common over most of the western half of Kansas and Okla¬
homa. In west-central and northwestern Kansas, it partly,
and in the southern tier of Kansas counties from Barber
westward almost if not quite supplants the typical variety.
I have observed a single specimen in southeastern Colorado,
about midway between Kansas and the mountains. The
peculiar home of the variety is apparently the "Red beds"
country of the Cimarron basin, upon whose red terranes it
may possibly have had its origin, afterwards extending its
range by migration.
Apropos of the western range of Terrapane, it would seem
that it falls a little short of the eastern base of the Rocky
Mountains in Colorado. Prof. Geo. H. Stone states that, in
his twelve years of residence here, he has never observed it
in the vicinity of Colorado Springs. Prof. William Strieby,
who resided for two years at Santa F6, states that he has ob¬
served a single specimen of the box-tortoise in New Mexico,
though he does not now remember the exact locality.
The Three-toed Box-tortoise, Terrapene triunguis, Ag.,
seems not to have been recorded from Texas, though it is
known from Indian Territory and Louisiana, so that its oc¬
currence in Texas is not unexpected.
I am indebffed to Mr. G. H. Ragsdale for several speci¬
mens of this species which are now before me from Gaines¬
ville, Texas, which is apparently the most westerly locality
known for its occurrence. That it will be found yet a little
further west in the valley of the Red river, is not improbable.
38
COLOEADO COLLEGE STUDIES.
At Gainesville, as doubtless in Indian Territory, the range
of this species and that of T. ornata, Ag., overlap. The
T. triunguis, however, keeps mainly to the more or less
wooded bottom-lands, as Mr. Ragsdale informs me, while
T. ornata, chiefly an open prairie species, is sometimes found
in the timber also.
The specimens of triunguis from Gainesville are larger
than those of ornata from the same place; and the high,
rounded carapace, with broad, flat, yet abruptly elevated
carina on the third and fourth vertebral scutes and bones
(usually seen also on the posterior part of the second), the
much less transverse second to fourth vertebral scutes, the
greyish olive-brown color, sometimes relieved by ornata-like,
dark and yellow subradial markings especially upon the ex-
centric place of origin of the concentric imbrications, the
more depressed skull and orbit and consequently more ob¬
liquely placed jugal bone, the possession of three claws only
on eacb posterior foot, and the essentially woodland habit,
are all peculiarities which distinguish the former species, as
from the latter. Both the fore and the hind limbs of the
only present example in which the skeleton is preserved have
the phalanges 2,3, 3, 2,1, those of the fourth and fifth digits of
the hind limb being rudimentary and these digits without
claws.
I am also indebted to Mr. Ragsdale for a shell and skull
of the Keeled Mud-turtle, GoniocJietys carinata, Gray, and
the same of Chrysemys elegans, Wied., which he collected in
Elm Fork of the Trinity river at Gainesville.
Gerrhonotus infernalis, Baird.— Cope has recorded this
species from Helotes creek, near San Antonio, and from
Wichita county, Texas. It is common in Hays and in the
western part of Travis county. In the summer of 1893, I
observed it in the Cross-Timbers, between Roanoke and
Lewisville, extending its known range somewhat eastward.
The little burrowing snake, Stenostoma dulce, B. & G.,
almost the sole representative of the family Typhopidce in
the United States, was also taken in the Cross-Timbers, at a
HERPETOLOGICAL NOTES FROM KANSAS AND TEXAS. 39
point about five miles west of Lewisville, considerably north¬
east of the most northeastern record with which I am ac¬
quainted (Bexar and Erath counties: Cope).
A red and black example of Contia episcopa isozona,
Cope, was captured in the road a few miles west of Sun City,
Kansas, on the point of the divide between Medicine Lodge
river and Elk creek, and was sent to me several years since
by Mr. Wm. A. Sherrill. Of the several phases described
from western territories by Cope in the Proceedings of the
Philadelphia Academy of Natural Sciences, this specimen
most resembles, and indeed almost precisely tallies with that
from Utah. I may remark in this connection that, of a small
collection of reptiles which I received a few years ago, through
Mr. John Pym, from southwestern Utah, all were, to my sur¬
prise, species common in Kansas.
In September, 1886, coming down the valley of the Cim¬
arron river from New Mexico, I first noticed the little Sonoran
toad, Bufo debilis, Girard, near the Z H ranch in the Public
Lands (now Beaver county, Oklahoma), at a point thirty-five
or forty miles west of the southwest corner of Kansas. The
species was observed a few days later in great abundance and
activity (during rainy weather) in Morton county, Kansas,
and in the southern part of Hamilton county. I have collected
a single specimen in the western part of Barber county,
Kansas, also.
THE CHOCTAW AND GRAYSON TERRANES OF THE
ARIETINA.
BY F. W. CBAGIN.
The " ram's horn oyster," Exogyra arietina, F. Roemer,
is the characteristic fossil of a column of sediments, the
so-called Exogyra arietina marl, that in Hays, Travis and
Williamson counties, Texas, consists mostly of calcareo-
argillaceous, and more or less ferruginous marl, and attains
a thickness of sixty to eighty feet, occupying the interval be¬
tween the top of the Washita limestone of Shumard and the
base of the Shoal creek limestone of Hill. This column was
recognized by Dr. Shumard as an important member of the
Cretaceous section of Texas, and was named by him, the
Exogyra arietina marl-, and this name, either as it originally
stood or under such slight variations of form as " the Exogyra
arietina clay," " the Arietina marl," etc., has been used for it
by most later writers. The same formation outcrops, with
more or less interruption by faulting, mantling, etc., and with
more or less variation in thickness and lithological character
southwestward to the region of El Paso. Its detail in this
direction being less known than that of its northward exten¬
sion, will not here be discussed. From Austiu to the Red
river valley in Cooke and Grayson counties, the Arietina be¬
comes, as TafiP has shown, gradually reduced in thickness and
decidedly more calcareous. For this calcareous northern
phase of the Arietina which, in the Red river valley, occupies
the entire interval between the summit of the Pawpaw clays
of Hill and the base of the Dakota sandstone. Hill has recently
proposed the name. Main-street limestone.*
The Main-street limestone, however, consists of two mem¬
bers. Its dual character has been independently determined
in the field by tbe present writer. But the members that
compose it were first recognized as terranes by Taff in his
second Report on the Cretaceous Area North of the Colorado
* BuUetin of the Geological Society of America, V., 330.
CHOCTAW AND GRAYSON TERRANES OP THE ARIETINA. 41
River,* who correlated the upper member with the Shoal
creek (Vola) limestone.
THE CHOCTAW LIMESTONE.
The lower of these two members, the Choctaw limestone.,
is the limestone that, in Cooke and Grayson counties, rests
upon the Pawpaw clays (and sands) of Hill, and a typical
locality of which is at the quarry owned by Mr. J. T. Munson
et al., on the summit of the Pawpaw creek bluffs, southeast
of the Union depot of Denison. Thence it extends alon^
the brow of the creek-bluff to the northeastward, to a point
north of the Denison-Bonham road. It also outcrops exten¬
sively on Choctaw creek, from which it is named, and thence
westward on most of the tributaries of Red river, and on the
bluffs of the river itself to Gainesville, just west of the Cross
Timbers, where it takes a southerly course. It is well devel¬
oped in Denton county also, on Denton creek, near Roanoke.
Though softer and less durable than the so-called "quarry-
limestone" of Denison (at base of the Pawpaw clays), it is a
true quarry-limestone, and has been quarried for building
purposes not only at the quarry above named, but also at
many other localities. It is the same limestone that is called
by Taff. " the Exogyra limestone," in the report above cited
(pp. 281, 282, 283, etc.)
The thickness of the Choctaw limestone in Grayson county
is ordinarily about five feet, though locally it becomes a few
feet greater. In Cooke county the same limestone attains a
maximum thickness of ten or fifteen feet.
The paleontologic aspect of this terrane may be seen in
the following list, which includes most, if not all, of the
fossils that have been obtained from it:
FAUNA OF THE CHOCTAW LIMESTONE.
Hemipedina charltoni, Cragin.
Holectypus charltoni, Crag.t
Enallaster texanua^ Roemer.
Cucullcea recedens, Crag.j;
Cardium sp. (distinct from texanum)
Cardiuin{Protocard.)texanuni,Con.
* Pages 275-283.
t In the small peristome and posteriorly placed periproctt this species is closely
related to Holectypus castilloi, Cotteau, from which it differs chiefly in the form of
the periproct.
t This species is apparently distinct from C. terminalis, Conrad, of the Glen Rose
beds; but the question can perhaps hardly be settled till specimens of terminalis can
be found showing the details of the hinge.
42
COLOEADO COLLEGE STUDIES.
Terebratella wacoensis, Roem. Roudairia denisovensis, Crag.
Ostrea franklini, Coquand. Pholadomya ragsdalei, Crag.
Ostrea subovata, Shum. Pholadomya sancti-sabce, Roem.
Ostrea quadruplieata, Shum. Homomya washita, Crag.
Exogyra arietina, Roem. Paehymya austinensis, Shum.f
Lima wacoensis, Roem. Turritella denisonensis, Crag.
Vola texana, Roem. Turritella seriatim-granulata, R.
Trigonia clavigera, Crag. (?)*
All of the above-listed fossils were obtained by the writer
in this limestone at Denison, excepting the Holectypus,
which was recorded from the same limestone at Cedar Mills
(Taff) in the writer's "Contribution to the Invertebrate
Paleontology of the Texas Cretaceous."
Perhaps the most marked paleontological characteristic of
the Choctaw limestone is the plentiful occurrence of Tere¬
bratella wacoensis in association with Exogyra arietina. In
Grayson and Cooke counties, a good guide-fossil is Phola¬
domya ragsdalei, whose peculiar ornamentation usually suf¬
fices, even in fragments of casts or moulds, for its recogni¬
tion. This fossil has hitherto been found in the Choctaw
limestone only, and is by no means rare.
In the Arietina marl of more southerly counties, as Wil¬
liamson, Travis, and Hays, the Choctaw terrane is repre¬
sented by the calcareous transition from the marl of the me¬
dial, culminating horizon of Exogyra arietina to the Wash¬
ita limestone below, and its fauna is poorer and less peculiar.
There, as in northern Texas, Terebratella wacoensis and
Exogyra arietina are the leading members of its fauna, the
others being such as are common in the upper part (Denton
beds J) of the Washita limestone, such as Vola texana, Tur-
rilites brazosensis, etc..
♦ The only specimen of Trigonia that I have seen in the Choctaw limestone is a
cast of a smaU one, that does not show the character of the ornamentation, but
agrees in size and form apparently with T. clavigera^ and is probably that species,
T. clavigera is the common Trigonia of the Denton marls, and resembles T. emoryi^
with which Hill has apparently confused it, only in badly worn specimens. Com¬
paring, in numbers, finely preserved specimens of T. clavigera from the Denton
marls of Cooke county, Texas, and the Chickasaw Nation, with such of T.emoryi
from the Walnut clays, confusion of the two species is impossible. T' crenulata^
cited by Taff from the Denton marls, does not occur in rocks of the Comanche series.
t Not *^''Pachyma" as it is often spelled and pronounced.
t The Denton marl was clearly defined as to position, paleontology, and typical
locality by Taff, by means of a detailed section, in the Fourth Annual Report of the
Geological Survey of Texas, Part I, p. 272, and, though he failed to apply it elsewhere
in the same report, this name has priority over the later name, "Marietta" proposed
by Hill for the same terrane.
CHOCTAW AND GRAYSON TERRANES OF THE ARIETINA. 43
THE GRAYSON MARLS.
The Choctaw limestone is conformably succeeded by the
Grayson marls, passing up into them through a horizon of
sometimes quite abrupt, sometimes more gradual transition,
the marls being unconformably overlaid by the Dakota sand¬
stone. In their northeasterly exposures, the Grayson are
chiefly yellow, highly calcareous, sparingly arenaceous marls,
of such consistency as to crumble readily under the hand or
break into rough lumps under light blows of the hammer,
but which contain, especially in the lower parts, irregular
concretionary tracts of cement-like hardness and texture.
They yield rapidly to the weather and are hence often absent
or reduced in thickness by erosion, both Predakota and
recent. Again they occur only as slopes, grass-grown or
mantled with debris from the overlying Dakota. In Denton
county the Grayson terrane consists of alternations of marl
and limestone,* and attains a thickness of thirty to forty
feet. In Travis county it contains, in the upper part, beds of
hard limestone charged with Gryphma mucronata, and there,
as elsewhere south of the Brazos, it is overlaid conformably
by the Shoal creek limestone, into which it seems to graduate
through the basal part of the latter.
In Northern Texas, where the thickness of the Arietina is
reduced, the Grayson marls have a thickness of fifteen to
twenty-five or thirty feet.
A typical locality of the calcareous yellow marl phase,
showing its basal transition to the underlying limestone, may
be seen at the cut and fill of the once projected D. B. & N. O.
railway, between Pawpaw creek and a right-hand branch of
the same immediately southeast of the quarry above cited as
typical for the Choctaw limestone.
The Grayson marls were considered by Tatf to be the
equivalent of the Shoal creek, or Vola, limestone of the
Austin district, %nd were referred to by him as the Vola
limestone and marl in his second " Report on the Cretaceous
Area North of the Colorado River," which was published in
the Fourth Annual Report of the Geological Survey of Texas.
* See Taff's Elm creek section, in Fourth Ann. Rep. Geol. Surv. of Texas, Pt. I, p. 280.
u
COLORADO COLLEGE STUDIES.
(See p. 277.) In the " Contribution to the Invertebrate Paleon¬
tology of the Texas Cretaceous," published in the same report,
the present writer recorded a few fossils from beds referred
to, in doubtful terms or in quotation-marks, as of Vola equiva¬
lency (I. c., p. 147, etc.). He there purposely implied doubt or
placed the word, "Vola, " in quotation-marks, quoting from
the labels accompanying the specimens collected by Mr. Tafif's
field-party, feeling doubtful concerning the supposed dis¬
covery of the Vola in that region and never having examined
the region personally. In the summer of 1893, however, after
the publication of his " Contribution," he visited Denison, in
the course of an extended expedition, and studied the matter
in the field, and so independently arrived at the same opinion
that has been announced by Hill in the Bulletin of the Geologi¬
cal Society of America (Vol. V) viz., that no sufiicient evi¬
dence of the existence of an equivalent of the Vola limestone
in the Red river district has as yet been found.
Palebntologically, the Grayson and the Shoal creek terranes
have little in common. In his "Mesozoic Echinodermata of
the United States" (Bui. 97 U. S. Geol. Surv.), Clark gives,
presumably on Hill's authority, the Shoal creek limestone as
the source of his Hemiaster calvini, the latter being appar¬
ently synonymous with the Epiaster hemiasterinus, nob., an
echinoid common in the Grayson marls in northern Texas.
It is possible that the Gryphcca mucronata of the Grayson
limestone beds of Travis county may extend up into the
basal part of the Shoal creek limestone; but to the best of the
writer's recollection, he has never observed such an occur¬
rence.*
The following list includes all of the fossils that the
writer has identified from the Grayson terrane, nearly all of
which have been collected by the writer in Grayson county:
♦ In a letter received from State Geologist Dumble of Texas, since this was
written, and just as this. MS. is going to press, speaking of the ' Vola,' he writes that
the Gryphcea extends up into the solid limestones to a height of four or five feet."
But from his use of the word, "limestones" (in the plural), I am in doubt as to
whether he here refers to the lower part of the main stratum of the Shoal creek
limestone, or to the separate bed or beds of solid limestone underlying it. In either
case, it would seem to indicate only a transitional horizon such as occurs at the
limits of most of the terranes of the Comanche series.
CHOCTAW AND GRAYSON TEBRANES OF THE AEIETINA. 45
FAUNA OF THE GRAYSON MARLS {AND MARLY LIMESTONES).
Cyphosotna volanum, Crag. Modiola pedernalis, Roem.
Holaster completus, Crag. Cardiuin{Protocard.)texanumfion.
Holaster nanus. Crag. Roudairia denisonensis. Crag.
Holaster supernus. Crag. Tapes dentonensis, Crag.
Enallaster in flatus, Crag. Cyprimeria texana, Roem.
Epiaster hemiasterinus. Crag.* Homomya washita. Crag.
Ostrea perversa. Crag. Turritella seriatim-granulala, R.
Oryphcea mucronata, Gabb. Turritella denisonensis. Crag.
Exogyra arietina, Roem. Nautilus texanus, Shum.
Exogyra drakei. Crag. Turrilites brazosensis, Roem.
Lima wacoensis, Roem. Sphenodiscus pedernalis, Roem.
Vola texana, Roem. Hoplites texanus. Crag.
Avicula dispar. Crag.
The Grayson fauna, like the Choctaw, is much poorer in
southern Texas than in northern. The more common forms
occurring in it in Travis county are, in the writer's experience,
the following:
Ostrea perversa, Vola texana,
Gryphcea mucronata, Plicatula dentonensis. Crag.
Exogyra arietina.
Hill has recorded from the beds of this terrane at Austin,
the following also: Terebatella wacoensis, Roem, Diplopodia
texanum, Roem, Protocardium texanum, Con., Pachymya
austinensis, Shum., and Asiarte robbinsi. White; in case of
the first and last, only a single example of each.
In both northern and southern Texas, the Grayson marl
is especially characterized by that peculiar form of Gryphsea
that, by Hill, Taff, and other recent authors, has usually been
regarded as a variety of G. pitcheri, Morton, and has been
called by Taff, "the Vola phase of G. pitcheri,''^ but has re¬
cently been recognized by Hill as the truly distinct G. mu¬
cronata, Gabb.
* This name has priority over that of *' Hemiaster calvini" a name subsequently
applied to the species by Clark, whose specimens are " from the Shoal creek lime¬
stone .... in Travis county." Owingtothe feebledevelopmentof the peripeta-
lous fasciole, the writer referred this species to the genus Epiaster it being, in fact,
intermediate between tj>at genus and Hemiaster in the one important character that
distinguishes these genera. Since, however, the peripetalous fasciole is present,^
though imperfectly, and in some specimens very imperfectly, developed, it would
probably be more consistent to refer the species to Hemiaster^ as Clark has done.
But if this be done, it is questionable whether the same generic disposition
should not also be made of the well known Epiaster " elegans, Shum, which, in the
most perfectly preserved examples, is also seen to have a feebly developed peripeta¬
lous fasciole.
46
COLORADO COLLEGE STUDIES.
With others, the writer formerly supposed that this shell
was a mere variety of G. pitcheri, but now fully confirms the
original opinion of Gabb and the revised opinion of Hill that
it is specifically distinct. While the Grayson Gryphaea often
more or less nearly approaches the so-called "Kiamitia
variety " of O. pitcheri, with respect to the elongated trian¬
gular outline of the shell, it presents important differences,
such especially as the truncate anterior border, the sharp
angulation of the sulcus, and the very prominent and com¬
pressed anterior and posterior folds of the left valve; and
these features are so constant under all the variation in shape
of the Grayson shell that, not only for stratigraphic purposes
and convenience of expression, but even on the strictest bio¬
logical grounds, this shell must be regarded as distinct from
G. pitcheri, while closely related to it.* Gabb's G. mucro-
nata and Conrad's G. navia are not considered by the writer
as synonymous, but the latter is regarded as merely an arched
and imbricated example of G. pitcheri, lacking (as do all of
the stratigraphically low-occurring Gryphseas of the Com¬
anche) the compressed folds (especially the anterior com¬
pressed fold) and truncate anterior border which are the
fundamental characteristics of the left valve of G. mucronuta.
At the above-given typical locality of the yellow marl
phase of the Grayson, there is, in the lower part of the marl,
a horizon of profuse occurrence of typical Exogyra arietina
and, just below this, one of Turrilites brazosensis and Hol-
aster completus. In the upper part of the marl at the same
locality, the Exogyra arietina is small and not abundant, the
Turrilites plentiful; hui Holaster completus has not been
obtained, and, if it occurs there, must be rare.f
The fauna of the Grayson marl presents some affinities
to that of the Choctaw limestone, but far more is peculiar to
either fauna than is common to both.
* strong incurvature of the beaks and the conspicuous and intervalled margins
of imbrication are also constant or nearly constaht features of G. mucronata, but as
these are features exhibited by some examples of G. pitcheri, they are not of equal
diagnostic value with the characteristics above mentioned.
t It is to be noted, however, that the latter species, like Holaeter simplex Ire-
quently occurs in groups, so that what has appeared rare or absent in a horizon
may, by some fortunate find, become locally abundant.
CHOCTAW AND GRAYSON TERRANES OF THE ARIETINA. 47
The relationships of the two faunae, as far as now known,
may be seen in the following table:
TABLE OF OCCURRENCE OF FOSSILS IN THE TERRANES^ OF THE
MAIN-STREET ARIETINA,
Diplopodia texanum....
Hemipedina eharltoni..
Orthopsis sp
Cyphosoma volanum—
Holectypus eharltoni...
Holaster completus
Holaster nanus
Holaster supernus
Enallaster in flatus
Enallaster texanus
'Epiaster hemiasterinus.
Terebratella wacoensis..
Ostrea franklini
Ostrea perversa
Ostrea quadruplicata...
Ostrea subovata
Gryphma mucronata ...
Exogyra arietina
Exogyra drakei
Plicatula dentonensis...
Lima wacoensis
o
Vola texana
Avicula dispar
Modiola pedernalis
Cucullcea recedens
Trigonia clavigera (?) ..
Astarte robbinsi
Cardium sp
" (Protocard.) texanum
Roudairia denisonensis...
Tapes dentonensis
Cyprimeria texana
Pholadomya ragsdalei
Pholadomya sancti-sabce..
Homomya washita
Pachymya austinensis....
Turriiella denisonensis....
" seriatim-granulata
•Nautilus texanus
Turrilites brazosensis...
Sphenodiscus pedernalis
Hoplites texanus
From this table it will be noted that, of forty-two species
found in the two terranes, only ten, or less than one-fourth
part, are common to them both, and that, of the eleven species
of sea-urchins, not a single species is known to occur in both.
The absence of Cephalopoda in the Choctaw terrane is also
noteworthy. Of Turriiella denisonensis, common in the
Choctaw, the Grayson has thus far yielded only a single
example. The Gryphcea mucronata is not known in the
Choctaw, nor d(*s Ostrea subovata seem to extend up into
the Grayson terrane. The latter observation essentially ap¬
plies also to the association of Terebratella wacoensis with
Exogyra arietina, although, as above noted, a single speci¬
men of the Terebratella has been found by Hill in the Gray-
48
COLORADO COLLEGE STUDIES.
son at Austin. If Ostrea quadruplicata extends up into the
Grayson terrane, or beyond the basal transitional part of it,
such occurrence is certainly rare.
A few of the species now apparently confined to one of
these terranes, will doubtless be found, sooner or later in the
other; but, even so, many of the forms that occur in both are
extremely rare in one while common in, and so, in a sense,
characteristic of the other; and it is obvious that the faunal
aspects of the two terranes, like the lithological, are—and are
likely to remain—far more conspicuous for their differences
than for their resemblances.
DESCRIPTIONS OF INVERTEBRATE FOSSILS FROfl THE
COHANCHE SERIES IN TEXAS, KANSAS AND
INDIAN TERRITORY.
BY P. W. CRAGIN.
The material described in this paper has been derived
chiefly from the Arietina beds of northern Texas, a small part
of it coming from rocks of lower horizons and elsewhere, as
noted under the "Occurrence" of the species. The specimens
have been collected by the writer, except as otherwise stated
below.
The types of the Kansas specimens are in the paleonto-
logical collections of the museum of Colorado College; those
of the others, in the private collection of the writer.
The designation, Kiowa shales, is proposed for the in¬
teriorly dark-colored and superiorly light-colored shales that
outcrop in several of the counties of southwestern Kansas,
resting upon the Cheyenne sandstone in their eastern, and
upon the "Red-beds" in their middle and western exposures,
and being overlaid by brown sandstones of middle Cretaceous
age, or Tertiary or Pleistocene deposits, according to locality.
The Kiowa shales are a locally modified northern exten¬
sion of part of Hill's Comanche series, cut off from the main
part by erosion. They are named from the place of their
typical occurrence, Kiowa county, Kansas; and in that county
they outcrop only in those southern townships which once
formed the northern part of Comanche county. The fossils
of these shales are chiefly those which, in Texas, are most
common in the Fredericksburg division; but a few of tbem
are such as are tnost characteristic of the Bosque division,
and a few others are such as either culminate in or are
peculiar to rocks of the Denison beds.
For explanation of the terms, Choctaw limestone, and
Orayson marl, see the preceding article.
50
colorado college studies.
Asteoecenia nidieormis, sp. nov.
Stock massive, broad and low, its breadth increasing more
or less from the base upward, its summit excavated, the prom¬
inent, narrowly-rounded border-region of the summit being
irregularly lobed; cells united by rather thicks walls, calyces
small, irregularly polygonal or slightly rounded-polygonal;
columella short; septa rather stout, their free margins appar¬
ently a little uneven, their'summits moderately depressed
below the level of the calyx-borders, the primary and sec¬
ondary septa six each, short septa of the third order also
appearing.
Measurements.—'M.aximvLva breadth of polyp-stock 102,
breadth at right angle to line of maximum breadth 95, height
29; average diameter of calyces, including half of the inter-
calycular walls 2, thickness of inter-calycular substance .4-.7
(average about .5) mm.
Occurrence.—The type was collected, several years since,
from the platform of arenaceous shell-conglomerate that caps
the Cheyenne sandstone and forms the base of the Kiowa
shales at Belvidere, Kansas. (No. 5 of the writer's Belvidere
section.) A second specimen was recently collected by the
writer, but was so poorly preserved as to be of little use for
purposes of study.
Hemipedina chaeltoni, sp. nov.
Test small, ronnd-pentagonal, arched above, concave be¬
low; apical disc and periproct moderately broad; peristome
considerably smaller in proportion to the test than in Pseudo-
diadema texanum, Roemer; pore-belts straight, the pores
somewhat elongated in the direction of the belt, the pore-
pairs simple throughout and somewhat oblique; ambulacral
arese half as broad as the interambulacral, each ornamented
with two rows of primary tubercles that are somewhat smaller
than those of the row of largest tubercles on the interambu¬
lacral arese, each primary tubercle being subtended by an
irregularly polygonal string of smaller (secondary) ones;
interambulacral arese with six rows of primary tubercles,
these being much larger in the middle row of each semiambu-
desceiptions of invertebrate fossils.
51
lacrum than in the others, the primaries subtended by
secondaries for the most part in polygonal strings; surface
of test closely granulated in the intervals between tubercles
on both ambulacral and interambulacral arese.
Measurements.—Height of test 11, breadth 25, greatest
breadth of periproct 3.5, breadth of peristome (about) 7 or
8 mm.
Occurrence.—The type of this species was obtained from
the Choctaw limestone, south of the Denison-Bonham road,
near the lime-kiln about a mile east of Denison, Texas. It
was associated with Exogyra arietina, Ostrea quadruplicata,
O. subovata, Lima wacoensis, Pholadomya sancti-sabce,
P. ragsdalei, etc.
The writer takes pleasure in naming this interesting
echinoid after his friend and sometime fellow-traveller, Prof.
O. C. Charlton.
Besides Orthopsis occidentalis, nob., this is the only rep¬
resentative of the section of Diadematidce with perforated
and non-crenulated tubercles known from North American
rocks.
Although a single recent species of Hemipedina is known
(H. cubensis, A. Ag.), this genus is known as a fossil, from
Jurassic and lower Cretaceous rocks only; and its occurrence
in the upper part of the Washita division therefore confirms
the conclusion which the writer has previously drawn from
the similar occurrence of Holectypus, that the Washita
division should be referred to an epoch not later than late
Neocomian.*
Pecten inconspicuus, sp. nov.
Shell small, thin, subcircular, a trifle higher than long,
slightly truncated anteriorly and posteriorly, right valve
gently convex, its outer surface smooth except for faint con¬
centric striae anc^ a few remote, subimbricate growth-lines;
umbonal angle sharp at apex, nearly a right angle; anterior
ear (imperfect in the type) reentrant below, as indicated by
the direction of the striae upon it, outline of posterior ear
*See " Contribution to the Invertebrate Paleontology of the Texas Cretaceous,"
in the Fourth Annual Report of the Geological Survey of Texas, Part II, p. 159.
52
COLORADO COLLEGE STUDIES.
making an obtuse angle, its posterior margin rather more
than one and a half times as long as its dorsal. Left valve
unknown.
Measuremenis.—Height 9.5, length 8.75, convexity of left
valve 1 mm.
Occurrence.—On slope of Pawpaw creek, east of Denison,
Texas, in red ochraceous shell-conglomerate of the Pawpaw
clays. The associate fossils are Osfrea quadriiplicata, Tapes
dentonensis, Yoldia microdonfa, Turritella seriatim-granu- -
lata, Splienodiscus, Turrilites, etc.
VOLA FREDEEICKSBUEGENSIS, Sp. nov.
This name is proposed for the species of Vola described
by Roemer from Fredericksburg,Texas, inhis Kreidebilduiigen
von Texas, as " Pecten quadricostatus, var.," and is based on
his description and illustrations (pp. 64, 65; PI. VIII, fig. 4
a, h, c).
The species is the ordinary one of the Fredericksburg
division of the Comanche Cretaceous series, being very com¬
mon in the Comanche Peak limestone of Texas and Indian
Territory, and in the lower parts of the Kiowa shales of
Kansas.
It is easily distinguished from V. iexanus, Roemer, by its
much narrower and more elevated ribs, more triangular form,
and usually (in adult examples) by its larger size.
It has been referred to by authors under various names;
but it is distinct from any of the species to which it has
hitherto been referred. It is, however, closely allied to
V. alpina, D'Orb.
Avicula dispae, sp. nov.
Shell small, semicircular, radiately ribbed, compressed,
very inequivalve, the left valve being feebly arched, its con¬
vexity greatest in the basal region and its basal margin more
or less overhanging that of the smaller flat-concave right
valve; anterior ears sharply delimited, nearly equilateral tri¬
angles; posterior ear feebly developed, narrow, rounded off
above on the distal part, that of the left valve not abruptly
separated from the body of the valve, that of the right valve
descriptions of invertebrate fossils.
53
scarcely observable; beaks inconspicuous, the entire umbonal
region strongly compressed, the beak of the left valve higher
than that of the right; valves thin; ligament double, the
outer part placed in an open groove, the inner in a triangular
pit under the beaks; hinge-plate of left valve broader than
that of the right; radial ribs of left valve large, broad, flat-
convex, separated by narrow, abruptly impressed intervals,
the intermediate ribs in the type-specimen not extending
over the somewhat strongly convex basal region, which is
smooth or finely concentrically striate and pearlaceous, but
suddenly truncated; ribs of right valve feebly developed,
narrow, irregularly tuberculated, obsolete on the ventral and
anterior parts; radial groove separating anterior ear from
body of valve, in the left valve, deeply impressed, and having
its counterpart on the right valve in a low ridge.
Measurements.—Height 20, length 33, breadth 5 mm.
Occurrence.—The type of this species is a finely preserved
shell found by the writer in the Grayson marl, on a draw of
Pawpaw creek, half to three-quarters of a mile southeast of
the Union depot at Denison, Texas, It was associated with
Exogyra arietina, E. dralcei, Turrilites brazosensts, etc., in
the lower part of the marl.
The ribs of the body of the left valve are fourteen in
number, and adjacent to either ear is a radially striated seg¬
ment about as wide as the widest rib. The anterior ear of
the left valve shows two or three rather coarse ribs on the
posterior part, the posterior ear being ornamented with radi¬
ating raised lines. In the narrow intervals between several
of these lines and between several of the broad ribs of the
posterior part of the body of the left valve, the hand-lens
reveals more or less regularly arranged elements that present
the appearance of cross-threads or obliquely compressed
tubercles.
I am not acqjiainted with any species that is closely anala-
gous to Avicula dispar.
Inoceramus comancheana, sp. nov.
Shell equivalve, obliquely and broadly rhombic-ovate,
more gibbous than that of I. labiatus, Schloth., the axis of
54
COLORADO COLLEGE STUDIES.
greatest dimension diverging from the hinge-line much more
widely than in the latter species; alar outline rounded; an¬
terior margin descending steeply in a nearly straight line for
a considerable distance in front of the beaks, then curving
rather suddenly away toward the somewhat prominently con¬
vex distal part of the basal outline, anterior and posterior
margins making nearly a right angle with each other; beaks
placed opposite the anterior extremity of the hinge, moder¬
ately inflated, and moderately elevated above the hinge-line,
anteriorly flattened, but not abruptly so; hinge-plate rather
short, broad, the ligamental grooves crowded, more numerous
and longer than in I. labiatus, though ample and shallow;
valves thin, ornamented with numerous concentric rib-like
folds, which, on the discal and ventral parts, are quite strongly
elevated and much narrower than the intervals between them.
Measurements.—Height.82, length 95, breadth 54, axis of
greatest dimension 107 mm. In some examples, the species
attains considerably larger dimensions.
Occurrence.—This is the common Inoceramus of the
Duck creek (lower Washita) limestone, or basal part of the
Washita division of the Comanche series. The types were
collected by Mr. J. T. Munson and the writer one to two miles
northeast of Denison, Texas. The species occurs also in the
Chickasaw nation, three miles north-northwest of Marietta,
in the same limestone. At both localities it is associated
with Pachydiscus marcianus,* Schloenbachia peruviana and
S. serrtaescens, Hamites fremonti, Epiaster elegans, var.
prcenuntius, etc.
In the upper part of the Kiowa shales of southern Kansas,
occur imperfect casts of an Inoceramus which I provisionally
refer to this species. In Clark county, Kansas, these are
associated with Ostrea quadruplicata and Ostrea franlclini.
^Ammonites [Pachydiscu8'\ brazoensis^ Shum. (1860), is a synonym of A. [F.]
marciana, Shum. (1854); but I am somewhat doubtful about the propriety of using
the older name, as the description and figure accompanyiDg it are those of a very
young specimen. It seems a strange circumstance that Dr. Shumard failed to
refer to the two names as synonymous. This circumstance, however, may indicate
either that he did not recognize in '' brazoensie his " marciana " of 1854, or that he
merely considered the older name invalid, as based on a young specimen and one
that did not show the suture.
descriptions of invertebrate fossils. 55
In Marcy's Red River Report (p. 193, PI. 6, fig. 2), Shumard
describes and figures an Inoceramus that "occurs rather
abundantly at Camp No. 4, Cross Timbers, Texas," referring
it to I. confertim-annulatus, Roem. That his description
and figure relate, not to the upper Cretaceous confertim-
annulatus, but to the species which I have here named
J. comancheana, is indicated not only by the figure that he
gives but also by the fact that the stratigraphic source of all
of the fossils that he described from " Cross Timbers, Texas,"
was evidently the middle part of the lower Cretaceous; i. e.,
the Comanche Peak limestone and the Duck creek (lower
Washita) limestone. Nearly all of these fossils are com¬
mon in, and chiefly characteristic of, the Comanche Peak
limestone; but the association of Schloenbachia peruviana.
Von B., with Pachydiscus marcianus, Shum.,* which he men¬
tions, is a feature of the Duck creek horizon and indicates
the presence of this horizon there also, and hence the prob¬
able presence there of the common Duck creek fossil, Inoce¬
ramus comancheana.
Inoceramus munsoni, sp. nov.
Shell (?inequivalve), elevated, obliquely triangular-ovate,
of moderate convexity; hinge short; beak of left valve elevated
high above the hinge-line, strongly flattened on its right
(inner) anterior quarter, its apex incurved as in I. sulcatus.
Park.; valves extremely thin, moulded with small, feebly ex¬
pressed, concentric undulations and striae and, on its anterior
third, with three large and prominent, wave-like, radial folds,
the foremost and shortest one of which forms a sort of shoul¬
der in advance of which the border of the shell is strongly
inflected to form the flat ante-umbonal area, the part of the
valve posterior to these three folds, presenting two broad,
obsolescent, low-convex, radial segments, the posterior one of
which mav be subdivided into two narrow folds.
♦
Measurements.—Of a left valve; height 57, length 53,
convexity 23, axis of greatest dimension 67 mm.; of a smaller
left valve, height 36, length 33, convexity 11 mm.
♦His Ammonites acuto-carinatus and Ammonites marciana. See 1. c., p. 197.
56
colorado college studies.
4
Occurrence.—In the Duck creek limestone, on Duck creek,
between one and two miles northeast of Denison, Texas.
This fossil is much less common than the I.comancheana.*
The specimens occur as casts, with occasional remnants of
the shell.
The species is named after Mr. J. T. Munson, of Denison,
in recognition of the generous aid which he has shown him¬
self every ready to lend to scientific research.
Nucula chickasaensis, sp. nov.
Shell small, of moderate convexity, though more convex
than that of N. catherina nobis, ovate-triangular, the anterior
side descending directly and subvertically from the low, nearly
terminal beaks, giving the anterior part of the profile an
obliquely truncate appearance, posterior cardinal side slightly
convex, posterior extremity somewhat narrowly rounded, base
long, gently convex, and suddenly curving upward at its
anterior end; shell divaricately ornamented with fine and
close raised lines and strise, each of which has the apex of its
V-like angulation directed toward the beak, the anterior arms
of the Vs being gently concave toward the anterior, or supero-
anterior part of the shell, the posterior arms presenting a
gentle concavity upward and backward, the angle of divarica¬
tion, at apex, somewhat less than a right angle.
Measurements.—Height 11.5, length 14, breadth 8 mm.
Occurrence.—The type of this species was collected by
my wife from the Comanche Peak limestone, overlooking
Little Hickory creek south of Overbrook in the Chickasaw
♦ The writer would here note that the species, ^^Inoceramus muUistriattis" which
he published in his "Contribution to the Inyertebrate Paleontology of the Texas Creta¬
ceous," is invalid, having been based on a mutilated specimen of Avicula pedernalis^
as he discovered when, on his expedition of July to September, 1893, he collected
specimens of the latter fossil, no specimen of which, sufficiently well preserved to be
easily recognized by one not previously acquainted with the species, had been avail¬
able for his study in the museum of the State Geological Survey prior to his leaving
Austin. Not suspecting the former presence of the large wing, which had been
broken off, on the imperfect specimen examined, the writer was led to refer this
specimen to the genus Inoceramus, in view of its transversely fibrous shell-structure
and of its degree of resemblance in form to Inoceramns sublcevis, overlooking the
fact that the shell of Axncula also has such structure.
descriptions of invertebrate fossils.
57
Nation. It was associated with Holectypus planatus, Exogijra
texana, Turritella seriatim-granulata, etc.
The species belongs to the subgenus ^cj7a.
Cardidm quinordinatum, sp. nov.
Shell of rather small size for its genus, rounded-triangular,
subequilateral, the anterior and posterior sides of the outline
slightly concave in the upper and convex in the lower part,
the basal margin being evenly rounded, the part of the out¬
line formed by the arched umbonal summit being very ob¬
tuse; beaks subcentral, large, arched strongly, the arch rising
high above the hinge-line; surface ornamented with some¬
thing like twenty broad, prominent, rounded, spinigerous
costse separated by narrow plain-bottomed intervals, the costal
spines being of the squamous type, having the form of caret-
shaped hoods, and being closely set in five radial ranks on
the same number of slightly elevated rays on each costa, the
rays being separated by striseform grooves. The intercostal
valleys are a little less than two-fifths as wide as the cost®.
Of the five spinigerous rays on each costa, the middle one is
relatively larger and more coarsely spined than those adjacent
to it, the two outermost being the smallest of all.
Measurements.—Height 21, length 19, breadth 16 mm.
Occurrence.—There is a little doubt as to the source of
the two type-specimens of this species. They were, however,
almost certainly collected at a ledge of the Washita limestone
a little east of Georgetown, Texas, in association with Ostrea
roanokensis, Pleurotomaria robusta, and SchloenbaShia ana-
tina.
Koudairia denisonensis, sp. nov.
Shell among the larger representatives of its genus, ele¬
vated-triangular, the lateral profile of its cast approaching an
isosceles triangle with convex base, but the supero-posterior
part of that pr(tfile presenting, as in R. quadrans,* a low
*See American Geologist, Vol. XIV, PI. I, fig. U. R. quadrans should be com¬
pared with the shell described in the writer's "Contribution to the Inrertebrate
Paleontology of the Texas Cretaceous," as Trigonia securiforms, with which it is
quite likely that it will prove to be identical. There can be little doubt that the
latter species belongs to the genus Roudairia.
58
colorado college studies.
shoulder (the angulated summit-line of the feeble keel made
by the apposed edges of the valves) a short distance from the
beaks; valves of quite moderate convexity; beaks placed a
little in advance of the middle, narpow, their tangent apices
curved inward and downward, but inclined forward in only a
very slight degree; anterior and posterior slopes more or less
flattened, the posterior separated from the discal slope, in the
cast, by a faint angulation; discal and anterior slopes orna¬
mented with unequal concentric lines, and the posterior slope
with 35 or more radial raised lines, which are relatively much
finer than those of R. quadrans.
Measurements.—Height 78, length 69, breadth 50 mm. A
second specimen is relatively longer, measuring, height 71,
length 67, breadth 46 mm.
Occurrence.—The types of this species are several casts,
two of which show the character of the ornamentation. They
were Collected by Mrs. F. W. Cragin, Mr. J. T. Munson, and
the writer, chiefly from the Grayson marl, at the old D. B.
and N. O. railway cut about half a mile southeast of the Union
depot of Denison, Texas. A single example, somewhat smaller
than those from the marl, was obtained from the Main-street
limestone on the summit of the creek-bluff adjoining.
Among the considerable number of fossils found associated
with the Roudairia denisonensis, are Exogyra arietina, E.
drakei,Vola texana,Aviculadispar,Sphenodiscuspedernalis,
Turrilites brazosensis, etc.
Pholadomya eagsdalei, sp. nov.
Shell large, triangular-ovate, compressed, multicostate;
umbonal region somewhat elevated, but beaks not strongly
arched; much the larger part of the shell ornamented with
straight to slightly curved radial cost®, which are narrow like
the intervals between them and more or less crossed and in¬
terrupted by raised, concentric growth-lines; anterior area of
shell ornamented with a system of concentric, strongly curved,
loop-like to more or less nearly quarter-circlet costse which
are quite independent of the concentric, elevated growth-lines
and are severally continuous at their attenuated posterior
descriptions of invertebrate fossils.
59
ends with the similarly attenuated supero-anterior ends of
the radial costse, forming with the latter, at the place of meet¬
ing, a series of beakward-pointed V-like angles.
Measurements.—(Approximate.) Height 70, breadth 10,
length 100-105 mm.
Occurrence.— Several molds of this species were found
by Mr. J. T. Munson and the writer in the Choctaw lime¬
stone, with Ostrea quadruplicata, Exogyra arieiina, Tere-
bratella wacoensis, etc., on the Pawpaw creek bluffs east and
southeast of Denison, Texas. For an example from Cooke
county, Texas, showing the shell itself and the major part of
both valves, the writer is indebted to Mr. G. H. Kagsdale,
after whom the species is named,
A loan-collection now in hand contains one example of
this beautifully and uniquely marked species from a county
in Texas south of the Red river tier, but it is not now pos¬
sible to ascertain its exact source.
As all of the specimens of this fossil that the writer has
seen are more or less imperfect, there remains some doubt as
to the generic position. But the species is so striking and
unique in the character of its ornamentation that there will
rarely be difficulty in recognizing it, even in the imperfect
specimens in which it commonly presents itself.
Homomya washita, sp. nov.
Shell large, curved-oblong, closed or nearly closed an¬
teriorly and closed along the dorsal margin back of the beaks,
obliquely truncated and gaping posteriorly, the breadth
usually a little greater than the vertical dimension from
hinge-margin to ventral margin, the length equal to some¬
what more than one and a half times the breadth, the greatest
breadth being about half way between the beaks and the mid-
region; beaks nearly terminal, low, swollen, obtusely tangent,
their bases long^n the direction of the length of the shell
and rising at a very low angle from their posterior origin to
their rather broadly rounded summits; surface marked only
with concentric growth-lines and undulations, and sometimes
showing distally two or three broad growth-zones or stages.
60
colorado college studies.
Measuremenis.—Height (to summit of beaks) 92, vertical
dimension from base to hinge-line 76, length 120, breadth
80 mm.
Occurrence.—Cyphosomci volanum, Enallaster in-
jlaius, Ostrea roanokensis, Exogyra arietina, E. drakei,
numerous large Vola iexana, Roudciiria denisonensis, and
many other fossils, in the Grayson marl in the abandoned
D. B. and N. O. railway cut about half a mile southeast of
the Union depot of Denison, Texas; also in the Choctaw
limestone, with Ostrea quadruplicata, Exogyra arietina,
Terebratella wacoensis, Pholadomya ragsdalei, etc., on sum¬
mit of Pawpaw creek bluff southeast and east of Denison.
The species is apparently more common in the limestone
than in the marl, but the specimens thus far observed from
the former are usually smaller and more poorly preserved
than those from the latter.
Tellina sub^qualis, sp. nov.
Shell subsequilateral, elongate-elliptical, the height con¬
tained twice in the length, the outline a little narrowed toward
either extremity, slightly more toward the posterior than
toward the anterior, the dorsal outline gently declivous and
nearly straight for some distance on either side of the beaks,
the anterior outline evenly rounded, angulation of the pos¬
terior slope scarcely appreciable in the cast, valves of moder¬
ate convexity, the curvature across the discs being remarkably
uniform from a little below the umbonal summits to the
basal margin and from the anterior to the posterior extremity;
beaks low and obtuse; pallial sinus extending forward a little
beyond the point directly opposite the beaks, its fundus
rounded.
Measurements.—Height of cast 14.5, length from anterior
extremity to a point opposite the beaks 13.5, from posterior
extremity to the same point (about) 15.5, convexity of cast of
right valve about 3 mm.
Occurrence.—On Pawpaw creek, east of Denison, Texas,
in ochraceous shell-conglomerate of the Pawpaw clays; with
Yoldia microdonta, Turritella seriatim-gramdata, etc. Oc¬
curs chiefly as casts with fragments of shell, and as molds.
descriptions of invertebrate fossils.
61
This Tellina is closely related to T. equilateralis, M. and
H., of the Fox Hills division of the upper Cretaceous; but
comparison of the Denison specimens with Meek's figures of
that species shows that they represent a decidedly more
elongate form than the latter.
CoRBULA CRASSICOSTATA, sp. nOV.
Shell triangular-ovate, gibbous, nearly as broad as high,
short; gaping posteriorly by a short, conically inflated, gently
truncated rostrum, which is placed high above the base of
the shell; umbones placed in advance of the middle, that of
the right valve only moderately high arched, its summit ob¬
tuse; surface ornamented with very coarse, flattish-topped,
concentric ribs, separated by abrupt, deep, narrow intervals.
There are seven or eight of the ribs on the basal half of a
right valve the same number of millimeters high.
i
Measurements.— Height 7.5, length 10, breadth about
7 mm.
Occurrence.—In arenaceous limestone bands of the Kiowa
shales, at Belvidere, Kansas; in Nos, 2-4 of the writer's
"Belvidere Section."
So far as the writer can judge from material now in hand,
the similar Corhula that abounds in the condition of casts
and molds in the ochraceous shell-conglomerate of the Deni¬
son beds, at Denison,Texas, presents no differences of specific
value from the Kansas shell above described. The casts
show that the pallial line is very sharply impressed.
Margarita* brownii, sp. nov.
Shell of moderate size and thickness, the postlabial region
becoming thicker at maturity, depressed-conical, deeply um-
bilicated; whorls four and a half, somewhat depressed, rounded,
smooth, the body-whorl obtusely angulated below, becoming
much thickened*and tumid on the part near the aperture, the
tumid portion, however, flattened a little on the quarter be¬
tween base and umbilicus; aperture round, much smaller
than the nearly oblong and sharpened peristome, the latter
being continuous except on about one-fifth of the circuit, and
62
colorado college studies.
the beveled zone between the aperture and the peristomial
edge being continuous around the aperture, broadest where
it rests against the whorl above, narrowest on the basicolu-
mellar quarter; inner lip free opposite and below the umbili¬
cus, adnate above it, the free portion everted so as to encroach
slightly upon the umbilicus and to overarch about one-third
of it; umbilicus somewhat narrowed, but deep, striated or
costellate, each costella terminating interiorly in a slight en¬
largement, the series of narrow tubercles thus produced giving
the angulated border of the umbilicus a crenulated aspect;
umbilico-basal angle not extending over the tumid labial
region. The fine growth-lines of the shell are directed
obliquely backward from the suture above, on the upper part
of the whorls, becoming transverse on the lower part of the
body-whorl.
Measurements.—Height 10.5, breadth 14.5 mm.; diver¬
gence of slopes 109 degrees.
Occurrence.—In the Caprina limestone of Travis county,
Texas, in the south bluffs of the Colorado river, west of South
Austin; associated with Requienia patagiata, Monopleura
marcida, M. pinguiscula, Lucina acute-lineolata, Nerinea
pellucida, and other fossils of the Barton creek and Deep
Eddy bluff fauna.
For the type-specimen, I am indebted to Prof. B. S. Brown,
after whom the species is named. The specimen, like others
of this fauna, is beautifully preserved in calcite, and has a
bright red tinge, due to a thin incrustation of iron oxide.
Neeitoma marcouana, sp. nov.
Shell small, of moderate thickness, depressed-subglobose,
oblique, consisting of apparently three and a half whorls;
spire sublateral, small, eroded; body-whorl large, ventricose,
evenly rounded, nearly smooth, its upper part with feebly
elevated costellse, extending obliquely upward (that is, toward
the suture and at the same time somewhat toward the aper¬
ture), and separated by round-bottomed, groove-like intervals
of about the same breadth, that begin, in part abruptly, at or
just above the periphery; periphery and base of body-whorl
descbiptions of invertebrate fossils. 63
smooth, or marked only with ordinary growth-lines; aperture
obliquely and rather narrowly ovate; inner lip with a callous,
strongly flattened, and without teeth; outer lip with a moder¬
ate, shallow, broadly rounded excavation just below the peri¬
pheral line. No umbilicus. The uneroded portion of the
spire rises but little above the body-whorl.
Measurements.—Height 10, breadth 10.5 mm. Costellse
of body-whorl, about 3 in 2 mm. A Belvidere example col¬
lected a few years ago, and not at hand for measurement, is
somewhat larger than the type-specimen from which these
dimensions are taken.
Occurrence.—In the Kiowa shales of Kiowa county, Kansas,
in No. 3 and the upper part of No. 4 of my Belvidere section.
In the past ten years, the writer has collected several speci¬
mens of this shell, of which two or three were obtained at
Belvidere; and one, of probably—though he cannot say posi¬
tively—the same species, in limestone-bands in these shales,
just west of Windom, McPherson county, Kansas.
This adds another shell of Jurassic type to the fauna of
the Pre-Washita part of Hill's Comanche series.
The species is named in honor of Mr. Jules Marcou.
Solarium chigkasaense, sp. nov.
Shell rather small, discoidal, slightly concave above, more
so below; whorls five, all exposed above and (probably all)
below, in contact and slightly embracing, inequilaterally
rounded-subquadrate in cross-section, broader than high,
flattened above, the upper surface of each whorl dropping a
little lower than that of the whorl next outside of it, the
superior suture distinct, inferior surface of body-whorl raised
into a somewhat prominent rounded shoulder, periphery of
body-whorl rounded; cross-section of cavity near aperture
oblique, inequilaterally ovate, or rounded-triangular, trans¬
verse (that is, broader than high), but far less so than in
Koemer's Solarium planorhis, outline of the cavity and that
of the exterior of the shell in the cross-section not parallel
with each other, the shell being relatively much thickened at
the corners; upper side of whorls marked with ordinary
64
COLORADO COLLEGE STUDIES.
growth-lines which are crossed by a series of subremote re¬
volving striae, the upper centripetal border of the whorls
being puckered so as to give it a crenulated appearance;
ornamentation of lower surface of shell unknown.
Measurements.— Greatest breadth of shell 13.5, height
(that of the body-whorl) 4.3, height of cross-section of cavity
near aperture 2.5, breadth of same 3 mm.
Occurrence.—A single siiecinien of this shell, in situ, was
found by the writer in the Comanche Peak limestone on a
south branch of Little Hickory creek, a few miles north and
a little west of Marietta, Indian Territory. It was associated
with.Enallastertejcamis,Volafrederic1csburgensis, Turritella
seriatim-granulata, Tylostoma tumida, and Schloenbachia
peruviana.
Viewed from above, this shell bears close resemblance,
even in the oblique and slightly wavy apertural border, to
Solarium planorbis, Roemer, as figured in Palmontologische
Abhandlungen, Band IV, Tafel XXXI; but in apertural view
(a section immediately back of the aperture), the body-whorl
is seen to be quite different from that species as figured, with
respect to shape, thickness of different parts of the section of
the shell, and form of the cavity. The apertural view of the
present shell does not exhibit that very strongly and equi-
laterally compressed form of whorl, with parallel-outlined
and uniformly thick-walled cavity, that Roemer's figure rep¬
resents (fig. 14c, lac. cit). Indeed, that view of the present
shell may be described as intermediate between the figure
just cited and that of Euomphalus subquadratus, M. & W.,
given in Volume V of the Geological Survey of Illinois, PI.
XXIX, fig. 13 b, so that it would seem not an unreasonable
question to ask, whether the species could not be referred to
the genus Straparollus (which survived till the Jurassic, ac¬
cording to Zittel), quite as well as to the genus Solarium.
It may be of interest to know, in comparing Austin rocks
with those of the Red river region, that in the same lime¬
stone, and not far away from the locality that yielded this
close ally of Solarium planorbis, the writer has found one of
the specific members of the peculiar Barton creek fauna of
descriptions of invertebrate fossils.
65
the Caprina limestone that yielded the S. planorbis; viz.,
Natica avellana, Roem.
Turritella denisonensis, sp. nov.
This name is proposed for a large, tall-spired, species of
Turritella that seems to bear considerable resemblance to
T. leonensis, Con., and is possibly only a variety of that species,
but which, instead of having all of the whorls convex and
evenly rounded, as they are understood to be in leonensis,
has only the spire-whorls so, the body-whorl being enlarged
and angulated or shouldered, presenting a strongly flattened,
sloping face on its upper (posterior) part, a broader flattened
face on its middle part, and a less strongly flattened face on
its lower part. The casts show weathered remnants of raised,
narrow, cariniform lines, separated by broad, depressed inter¬
vals, in each of which is a similar but feebler line; lines of
the body-whorl apparently irregularly turberculated, those of
the spire-whorls not obviously so on the only shell-fragment
observed. The shell has evidently consisted of not less than
ten or eleven whorls.
Measurements (of cast).—Height about 107, breadth of
body-whorl 40 mm.; angle of spire-slopes 21 to 24 degrees.
Occurrence.—The casts of this shell abound in the Choc¬
taw limestone, at the top of the bluff of Pawpaw creek east
and southeast of Denison, Texas. A single example was found
in the Grayson marl, in the cut of the abandoned D. B. and
N. O. railway, southeast of the Denison Union depot.
Vanikoro propinqua, sp. nov.
Shell rather small, depressed-subglobose, thin or of moder¬
ate thickness; whorls four, convex, those of the spire not
prominently so; body-whorl greatly enlarged, rounded, some¬
what narrower and more elevated than in V. amhigua, M. & H.;
spire rather low, proportioned almost exactly as in V. amhigua;
suture not dee^y impressed; axis (? perforate); aperture
rhomboidal-ovate, angular above, obtuse below; ornamenta¬
tion unknown.
Dimensions.—Somewhat smaller than V. amhigua, M.& H.,
the exact dimensions not mensurable owing to the imperfec-
66
colorado college studies.
tion of the labial region. Angle of slopes of spire a little less
than 90 degrees.
Occurrence.—In Nos. 3-4 of the Belvidere section of the
Kiowa shales, near Belvidere, Kansas. I have seen but one
specimen.
This shell bears a striking resemblance in form to that of
V. ambigua as figured by Meek in Vol. IX of the Hayden
U. S. Geological Survey, differing from it chiefly by the rela¬
tively somewhat more elevated body-whorl and aperture and
the smaller size. The surface of the shell is somewhat weather¬
worn in the type and does not reveal its original sculpture.
Anchura kiowana, sp. nov.
Shell small, consisting of six convex whorls; spire elevated;
suture impressed; wing of moderate size, consisting of a proxi¬
mal flange-like part, continued posteriorly across half or more
of the first spire-whorl, and a carinated falciform process;
carina gradually arising at the base of the falciform process
and traversing the latter to the extremity; falciform process
much shorter and less upturned distally than that of the
somewhat similar species, A. ruida, White, not rising to the
lowest level of the suture between the body-whorl and the
first spire-whorl, but having its point directed outward and
somewhat upward, so as to make a large angle with the axis
of the spire, extero-inferior outline of wing rounded and the
border between this and the canal sinuous, margin of upper
(flange) part of wing describing a slightly concave to sigmoid
outline and more or less thickened and reflexed; inner lip
provided with a moderately broad and prominent callous;
canal short and obliquely truncated; spire-whorls and posterior
half to two-thirds of body-whorl ornamented with narrow,
curved, subvertical ribs, or folds, of which there are about
twenty-four on the first spire-whorl, and with numerous re¬
volving striae, the latter ornamentation gradually becoming
prominent and superseding the ribs on the lower third to half
of the body-whorl.
Measurements.—Height 19, breadth of body-whorl, in¬
cluding excursion of wing, 15 mm.; angle of spire-slopes
about as in A. ruida, White.
descriptions of invertebrate fossils.
67
Occurrence.—This handsome little shell is common in the
Kiowa shales of Kiowa county, Kansas, especially in the lower
part of No. 8 and the upper part of No. 4 of the writer's
"Belvidere Section." (See Nos. 9 and 11 of the B^llletin of
the Washburn College Laboratory of Natural History, and
American Geologist of January, 1891.)
Some of the commonest of the many fossils associated with
it are Gryphcea pitcheri, Ca7-dium kansasense, Cyprimeria
texana,* Tapes belviderensis, Turritella seriaiim-granulata,
and Schloenbachia peruviana.
The Anchura also occurs in the arenaceous platform of
shell-conglomerate forming No. 5 of the same section, the ex¬
amples from this horizon, like the Turritellce from the same,
being larger and more coarsely ornamented than those from
Nos. 8 and 4. The flange of the wing also extends further
upward in specimens from No. 5, sometimes reaching to the
lower part of the second spire-whorl.
The writer has also collected this fossil in the lower third
of the Kiowa shales in Clark county, Kansas, in a draw of
Bluff creek nearly opposite the mouth of Hackberry creek.
The species is distinguished from Anchura ruida, White,
by the vertically costate body-whorl, by the shorter, differ¬
ently directed falciform process, and by having the alar carina
confined strictly to the wing and nearly to the falciform
process, instead of being common to the wing and part of
the body-whorl.
Nautilus washitanus, sp. nov.
Shell large, compressed nearly as much as in Nautilus
neocomiensis, D'Orb., the size, form and ornamentation being
essentially as described by Shumard for his Nautilus texanus,'\
the siphuncle, however, placed between the middle and the
dorsal (outer) side of the septum and (sometimes, if not
always) nearer to the latter side than to the middle.
Occurrence.—Common in the Washita limestone of Texas.
* Cyprimeria gradata, Cragin, which will probably prove to be the same as
C, texana^ Roemer, when the hinge-details and form-variations of the latter shall be
fully discovered.
t Transactions of the St. Louis Academy of Scieoce, 1, 590.
68
COLOKADO COLLEGE STUDIES.
Two species of Nautilus are common in the rocks of the
Washita division, viz., N. texanus, Shumard, and N. washi-
tanus, nobis, which have hitherto been confounded, owing to
their general external resemblance and the fact that, occur¬
ring more commonly as fragments than as complete speci¬
mens, they often cannot be easily distinguished except by the
position of the siphuncle, which is frequently not shown.
All of the critically available specimens of Nautilus that
the writer had observed from rocks of the Washita division, be¬
fore the publication of his " Contribution to the Invertebrate
Paleontology of the Texas Cretaceous," had the siphuncle in
the dorsal (outer) half of the septum, and the writer there¬
fore stated in that report that Shumard was in error in
alleging its position to be ventral. The writer is now ac¬
quainted with two types of Nautilus from the Washita
division and now admits the accuracy of Shumard's descrip¬
tion. So far as observed, however, the common species of the
Washita limestone is N. ivashitanus, the Nautilus of the
Denison beds being ordinarily N. texanus, as shown by its
having the siphuncle nearly at the limit between the ventral
(inner) and the middle third of the septum. The latter
species has been found by the writer in the Denison beds of
Denton and Grayson counties, Texas, and ranges up into the
highest terrane of these beds, viz., the Grayson marl.
VERTEBRATA FROM THE NEOCOMIAN 'OF KANSAS.*
BY p. W. CRAGIN.
The "Belvidere section," "Blue Cut Mound section," and
"Blnfif Creek section," mentioned below are the geological
sections which the writer published several years ago in the
Bulletin of the Washburn College Laboratory of Natural
History (]No. 11), and in Vol. VII of the American Geologist.
The first and second are in the southeastern part of Kiowa
county, Kansas, the third in the northeastern part of Clark
county.
The shales in which all of the described fossils were found
belong clearly to the Fredericksburg division of the Comanche
series, as shown by the occurrence in them of Sphenodiscus
pedernalis, Roem., Schloenbachia peruviana, Yon B., Holec-
typus planatiis, Roem., Exogyra texana, Roem., and many
other invertebrate fossils of that division.
That the Fredericksburg division corresponds to a part of
the European Neocomian, is clearly shown by its echinoderm
fauna, which, barely represented in Kansas, is well developed
in Texas.
Plesiosaurus mudgei, sp. nov.
Plate I, figs. 1-3 (? and also fig. 4).
About the size of P. neocomiensis, Campiche, as tested by
comparison of the type (Kiowa county) and Clark county
dorsal vertebrae with the measurements which Lydekker gives
of the casts of dorsal vertebrae of that species presented to
the British Museum by M. Campiche, but differing from
P. neocomiensis in the form of the vertebrae; dorsal vertebrae
moderately cupped, their centra having the three dimensions
(length, height,«and breadth across ends) nearly equal; con¬
striction as shown in figs. 2 and 3 of the plate.
* A private edition of this article, without the plates and with a different pagi¬
nation, was published May 12th, 1894. The shales herein referred to are the Kiowa
shales of the later-written articles on geology and invertebrate paleontology of the
Comanche series, published herewith.
70
COLORADO COLLEGE STUDIES.
Femur and humerus (as indicated by a Belvidere, Kansas,
specimen belonging with little doubt to this species) proxi-
mally enlarged so as to form a sort of head, slightly deflected,
or asymmetrical, but without any distinct neck and trochanter
such as are seen in Trinacromerum bentonianum, Crag.; flat¬
tened and laterally expanded at the distal extremity, and pro¬
vided with two distal facets.
Measurements.—Dorsal vertebra of type-specimen from
the Blue Cut hill; length of centrum 45, height of same 44,
height of vertebra to floor of neural canal 46, breadth of cen¬
trum at either extremity 45 mm. Humerus (or femur) from
about one mile south of the Belvidere railway station, pro¬
visionally referred to the same species: length (minus
epiphyses) 167 (as restored 171), girth at point of greatest
constriction 120, breadth at same point 41, greatest distal
breadth (estimated) about 70, thickness at distal part about
35 mm.
Occurrence., etc.— Remains of Plesiosaurus mudgei are
common in the Fredericksburg (Neocomian) shale of Kiowa
and Clark county, Kansas.
My announcement, several years since, of the occurrence
of Plesiosaurid remains in the Neocomian of southern Kansas
was based upon the discovery of two vertebrse of Plesiosaurus
in No. 5 of my " Blue Cut Mound section," one of which
vertebrae, attached to a specimen of Gryphcea pitcheri (the
vertebra illustrated on Plate I of the present article and con¬
stituting the type of P. mudgei) was turned over to the writer
by the collector, Mr. A. L. Diamond.
A year or two later, I examined a vertebra, then in the
possession of Mr. Henry Fares, which agreed closely with the
former one and which had been obtained with others in cen¬
tral Clark county.
Last autumn, fragmentary remains of what is probably
the same species were found by the writer at several points
near Belvidere, Kansas, in No. 3 of the "Belvidere section."
The best of the last-mentioned remains, a femur or
humerus, is figured on Plate I with the type-vertebra, and in¬
dicates paddles whose size is quite consistent with that of the
animal indicated by the Kiowa and Clark county vertebrae.
vertebrata from the neocomian of kansas.
71
Plesiochelys belviderensis, sp. nov.
Plate II, figs. 1-8.
Shell of moderate size, that of the type-specimen consider¬
ably smaller than that of P. solodurensis, Rut., anterior costal
bones spearhead-shaped, or triangular, pointed at the distal
end, their breadth contained twice or a little more than twice
in their length, the articulation for the first marginal bone
being relatively much shorter than in P. solodurensis—that is,
equal to one-fifth of the length of the costal itself; neural
bones narrow and elongate, the posterior lateral articulation
for the costal bone much longer than the anterior and nearly
straight (at least not distinctly of exteriorly concave outline
in the one well-preserved neural of the type-specimen), an¬
teriorly emarginate, the emargination in the type-neural being
ample, deep and trilateral; vertebral isthmus of type-neural
expanded beneath the middle of the bone so as to form a
thick, nearly rhombic, plate-like structure; upper surface of
shell (costal bones) ornamented with delicate vermicular
grooving and pitting.
Measurements.—Length of anterior costal bone 82, its
greatest breadth 38; minimum breadth of narrowest preserved
costal bone 24, maximum breadth of broadest 40; length of
one of the largest costals (nearly entire) 111; length of neural
bone 85, greatest breadth of same 24, posterior breadth of
same 14; length of a dorsal vertebra 82, anterior breadth of
same 28, posterior breadth of same 17 mm. If proportioned
to the anterior costal bone as in P. solodurensis, the carapace
of the type-specimen would have a length of some 800 milli¬
meters, or about a foot.
Occurrence.—The type of this species, consisting of the
two figured anterior costal bones, several other more or less
complete costals, the figured neural bone, and the figured
(in figs. 6 and 7 inverted) vertebra, were found by the writer
with the vertebra of {? Lamna) quinquelateralis about half
a mile south of the railway station at Belvidere, Kansas, at
the upper limit of the black shale that constitutes No. 4 of
the " Belvidere section."
72
colorado college studies.
Mesodon abeasus, sp. nov.
Plate II, figs. 18 and 20.
This name is proposed for certain pycnodont teeth of low,
rhomboidal form and feebly convex upper surface which
occur in No. 3 of the "Belvidere section," southwest of the
Belvidere railway station, and seem to agree with the larger
mandibular teeth of Mesodon. The specific name refers to
the occurrence in the type-specimen (see fig. 18) of two small
oblique facets produced at one end by attrition.
Measurements.—The type has a height (above root) of 3,
a length of 13, and a breadth of 6 mm.
To the vomerine set of the same species may belong the
rotund-oval, or nearly hemispherical teeth of similar height
but smaller size which occur not uncommonly at the same
locality and horizon, the largest now available example of
which (see figs. 15-17) measures about 6 and 7 mm. in minor
and major horizontal diameters.
( ? Lamna) quinquelateralis, sp. nov.
^late lly figs. 9 and 10.
The specific name, quinquelateralis, is applied to a species
of shark whose vertebrae differ from all others of which I have
any knowledge. The type-vertebra is short, much broader
than high, shallow-cupped, and more or less sharply pentago¬
nal ended.
Measurements.—Height 20, length 12, breadth 28 mm.
The two upper angles measure each about 130 degrees; either
lateral angle about 105 degrees. The lower angle is broad
and rounded.
Occurrence.—A single vertebra of this form was found by
the writer at Belvidere, Kansas, with the above-described
remains of Plesiochelys, in the upper part of No. 4 of the
" Belvidere section."
Hybodus claekensis, sp. nov.
Plate ii, figs. 11-U.
Fin-spine large, gently recurved, laterally compressed, the
sides being nearly flat, the anterior border subacute, or form¬
ing a sort of keel, the posterior part beveled on either side
VERTEBRATA FROM THE NEOCOMIAN OF KANSAS. 73
of the plate which bears the denticles, its general surface
minutely and unevenly striate and punctate-striate, there
being on the anterior part, a little back of the border (on one
side only as preserved in the type-specimen) one or two nar¬
row, low, longitudinal folds, or carina-Kke ridges; the greatest
breadth of the cross-section of the spine in the posterior part
of the denticuliferous portion contained twice in the length
of that section; denticles proportioned, arranged, and recurved
somewhat as in H. reticulatus, Ag., as figured by Zittel, their
compressed convex border with delicate but salient carina,
their broader, concave border rounded.
For minor details, see illustrations, of which figs. 11-13
are in part restored, and fig. 14 is a cross-section. The smaller
and more compressed denticles in fig. 12 represent the average
size of the denticles more accurately than the large ones.
Measurements.— Greatest breadth of the preserved part
of spine 13 mm. The entire length of the spine (of which
a length of a little more than 60 mm. is preserved) cannot
have been much less than a foot.
Occurrence.—The type-spine of this species was found
and presented to the writer by a member of the family of
Mr. W. E. Brown, in Clark county, Kansas, in the area of the
outcrop of the Fredericksburg Cretaceous shale, at the south
end of the "Amphitheatre" mentioned in connection with the
above-cited " Bluff Creek section."
Colorado College
Studies.
VOLUME VI.
inIVERSITY
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
•COLORADO SPRINGS, COLO.
MARCH, 1896.
\
cT
v. ^
THE PERMIAN SYSTEM IN KANSAS.
BY F. W. CRAGIN.
North and east of the Arkansas river, Permian rocks
occupy a comparatively narrow tract and represent only
the lower and middle parts of the system; but south of that
river they rapidly widen both their area and the strati-
graphic range of their outcrops. They are finely displayed
in the southern tier of Kansas counties,* from the eastern
border of Cowley to that of Meade, where they present a
section that is excelled nowhere east of the Rocky mount¬
ains save possibly in northern Texas.
The work of the earlier writers on the Permian of
Kansas, Swallow and Hawn, Meek and Hayden, New¬
berry, Mudge, etc., has been reviewed quite recently by
Prof. Prosser, in his "Classification of the Upper Paleozoic
Rocks of Central Kansas,"f but (in so far as concerns
Kansas) both those early authors and Prof. Prosser have
confined their attention to the lower and middle parts of
the system, as exposed in central and northern Kansas.;};
Meek and Hayden, Marcou and Geinitz, the earliest
students of the Permian ("Dyas") of Nebraska, had in
that State only lower and middle outcrops of the Permian
available for study. In 1854 and '55, Shumard, Hitchcock
and Marcou§ treated of rocks in the Canadian-Red river
district that belong to the herein-described Cimarron series
Marcou referring them to Permian ("Dyas") and Triassic,
Shumard and Hitchcock calling them Carboniferous. The
highest known terranes of the mid-plains Permian were
*Somewhat less fully in Oklahoma.
fC. S. Prosser, Journal of Geology, Vol. Ill, Nos. 6 and 7, 1895.
JProf. Mudge once visited Harper, Kansas, and there saw the
Harper sandstones, but referred them to the Dakota, an identification
which was at one time accepted by the present writer and some others.
§In Marcy's Red River Report, 1854; and in Rep. Secy, of War, 1855.
2
COLORADO COLLEGE STUDIES.
not Studied till 1886, when Prof. St. John observed them,
describing them the following year in his "Notes on the
Geolog}'^ of Southwestern Kansas,"* and referring them
doubtfully to theTriassic.
In the past four decades geologists have repeatedly
shown that the passage from the Carboniferous to the Per¬
mian system in Kansas is gradual and includes an interval
of so-called Permo-Carboniferous rocks which combine the
faunae of both systems. The evidence of continuity and
the question of the proper disposal of these intermediate
rocks have led to much difference of opinion, some even
having gone to the extreme of abandoning the Permian
as a system or age, merging it in the Carboniferous, in
attempting to avoid the difficulty of the situation.^ The
Permian in America is, however, a great and widely dis¬
tributed system, difficult of diagnosis though it often be,
from paucity of paleontological data. It is finely devel¬
oped in Texas, where it has great thickness and has been
foundij: to have occasional fossilferous horizons to within
less than 300 feet of its summit.
The Permian of the Kansas-Oklahoma basin un-.
doubtedly has many similarities to that of Texas, but it is
probably in only one or two of the terranes of the upper
Permian, especially in the Medicine Lodge gypsum, that
♦Fifth Biennial Report of the Kansas State Board of Agriculture.
tThe upper part of what is commonly called the Devonian sys¬
tem in America has so many of the characteristics of the Carboni¬
ferous that so high an authority as the late Dr. Newberry treated
it as part of the latter system. But to place the entire Devonian
in the Carboniferous, or vice ^'erm, on account of "its transitional
relation and the difficulty of assigning the intermediate rocks to
either system, would seem of questionable wisdom. The mutila¬
tion of the standard geological column by the transfer of the Per¬
mian to a lower than systemic rank, seems to be equally unneces¬
sary and to serve no useful purpose, while the retention of the Per¬
mian as a system and age in the majority of the leading geological
text-books and its degradation in others, is a confusion of terms of
which untechnical readers and students of elementary geology have
just cause for complaint.
JBy the labors of Mr. W. F. Cummins. See especially his
"Notes on the Geology of Northwest Texas" in the Fourth Annual
Report of the State Geological Survey of Texas.
THE PERMIAN SYSTEM IN KANSAS.
3
stratigraphic continuity or even parallelism of physico-
geographic conditions can be traced between them. It
therefore seems necessary to treat the Permian north
and south of the Ouachita mountain system as belonging
to two distinct basins, and profitless to attempt divisional
correlation between them.
The following schedule represents the writer's pro¬
visional section and
CLASSIFICATION OF THE ROCKS OF THE
SYSTEM IN KANSAS.
The Cimarron Series.
FORMATIONS.
Big Baein sandstone.*
Hackberry shales.
Day Creek dolomite.
Bed Bluff sandstones.
Dog Creek shales.
Cave Creek gypsums.
Flower-pot shales.
Cedar Hills sandstones.
Salt Plain, measures.
Harper sandstones.
The Big Blue Series.
FORMATIONS.
Wellington shales.
Geuda salt-measures.
Chase limestones. (Prosser.)
Neosho shales. (Prosser.)
In round numbers, the thickness of the Permian
rocks of Kansas is estimated at 2,200 feet, which may be
roughly apportioned among the leading subdivisions as
follows, it being borne in mind that there is great
geographical variation in the thickness of most of the
formations above the Chase and below the Medicine
Lodge: In th^ Big Blue series, 900 to 1,100 feet; in
♦The Day Creek and the Big Basin are the only formations of
the Kansas Permian that seem to be absolutely simple terranes, or
to consist each of a single bed.
PERMIAN
II.
DIVISIONS.
Kiger.
Salt Fork.
L
DIVISIONS.
Sumner.
Flint Hills.
4
COLORADO COLLEGE STUDIES.
the Cimarron series, i,ioo to 1,250; in the Flint Hills di¬
vision, 400, based oh 130 for the Neosho and 265 for the
Chase, as given by Prosser; in the Sumner division, 550 to
800, of which the Geuda measures occupy 300 to 400 and
the Wellington shales, 250 to 450; in the Salt Fork divis¬
ion, 900 to 1,000; and in the Kiger division, about 250.
For rocks near the base of the Permian as here rec¬
ognized, Prof. Broadhead records a southwesterly dip of
over 26 feet to the mile in the vicinity of the Elk-Cowley
county line;* and Prof. Wooster gives 20 feet per mile
as the westerly dip in the vicinity of the Greenwood-Butler
county line.-j- If the limestones pierced in the first few
hundred feet below the rock-salt at Caldwell and Anthony
belong, as supposed, to the Flint Hills division, it would
seem that the westward element of dip in the lower part of
the Kansas Permian continues with little change at least so
far west as Anthony, where the summit of these limestones
passes below sea-level. The summit of the limestones of
this division, on the Walnut creek bluffs, east of Arkansas
City, is a little more than 1,100 feet above sea-level; that
of the infra-salt-measure limestones at Anthony is 37 feet
below sea-level. Calling the difference of elevation of these
points 1,140 feet and their distance apart 56 miles, the west
element of dip of the summit-limestone of the Flint Hills
division for this distance averages about 20 feet per mile,
agreeing remarkably with the westing of dip observed by
Broadhead and Wooster in basal rocks of this division fur¬
ther eastward.
While the dip of the 7oiwr Permian rocks of southern
Kansas is south of west, that of the upper Permian, as
*G. C. Broadhead, in Transao. St. Louis Acad. Sol., Vol. IV, Part
3, p. 188.
fL. C. Wooster, in American Geologist, July, 1890. In his ar¬
ticle, "The Permo-Carboniferous of Greenwood and Butler Counties,
Kansas," he refers to the dip as "west" in his diagrammatic section,
and as "west by south" in his text. It is inferred from this that the
dip determined by him was in a direction nearly west, but a little south
of a true west line.
THE PERMIAN SYSTEM IN KANSAS.
5
indicated further westward in southern Kansas and north¬
ern Oklahoma by the Medicine Lodge gypsum, is chiefly
south with an easterl}'^ element. Thus the dip of the upper
Permian is nearly transverse to that of the lower. Whether
unconformity, or a quaquaversal flexure, or disparity of
sedimentation is the main cause of this discordant relation,
remains to be proven. But it is believed that if it be un¬
conformity, it is a succession of minor uncomformities
rather than a single large one, a supposition to which the oc¬
currence of conglomerates at several horizons in the middle
Permian possibly lends weight; while disparity of sedimen¬
tation must apparently be taken into account in solving the
problem.
Along the western edge of the area of their outcrop,
the Permian Rocks of Kansas are unconformably succeeded
by Cretaceous and Neocene sediments: or specifically by
the Cheyenne sandstone,* the Kiowa shales,* and the
Mentor beds* of the older Cretaceous (perhaps in part by
Dakota sandstone of the later Cretaceous also), and by
Loup Fork and later fresh-water sediments of the Neo¬
cene.
THE BIG BLUE SERIES.
The Kansas Permian presents itself in two series, the
lower of which is known to belong to the Permian by its
fossils and the upper of which is apparently connected
by a bond of stratigraphic continuity with the demon¬
strated Permian of Texas, as above indicated. The
lower series includes the strictly so-called Permo-Carboni-
*On tbeee formations, see "A Study of the Belvidere Beds," in
American Geologist, Vol. XVI, pp. 357-385; "The Mentor Beds," in
same volume, pp. 152-165; "Descriptions of Invertebrate Fossils from
the Comanche series in Kansas, Texas, and Indian Territory," in
Colorado College Studies, Vol. 5; and earlier papers by the writer
in Nos. 9 and 11 of tfce Bulletin of the Washburn College Laboratory of
Natural History, Vols. 6 and 7 of the American Geologist, etc. Also
"Outlying Areas of the Comanche Series in Kansas, Oklahoma and New
Mexico," by R. T. Hill, in American Journal of Science, September
1895.
6
COLORADO COLLEGE STUDIES.
ferous, together with several hundred feet of the un¬
mixed Permian, having its base a few feet above the Cot¬
tonwood limestone of Prosser (Fusulina limestone of Swal¬
low) and its upper limit at the summit of the Wellington
shales. It may be called the Big Blue series, from the Big
Blue river, which in northern Kansas crosses the some¬
what narrowed northern extension of its area of outcrop,
cutting both of its divisions. Its rocks include variously
colored, in part gypseous and saline shales, limestones
many of which are either siliceous or marly, rock-salt,
gypsum, and occasional beds of conglomerate. The shales
are drab, yellow, greenish, chocolate, maroon, red, white,
gray, blue, and dark slate-colored; but other than red in
the greater part. The series contains the extensive rock-
salt deposits of central and southern Kansas that have be¬
come of so great commercial importance within the past
few years, and whose products have been manufactured at
Hutchinson, Kingman, Kanopolis, Lyons, Anthony, and
other towns of that region.
In its lower portion, the Big Blue series is charac¬
terized by both Carboniferous and Permian fossils; in
higher horizons, by Permian fossils only; and in its upper
portion, is devoid of organic remains, so far as at present
known.
It embraces two divisions; the lower, or Flint Hills;
and the upper, or Sumner.
THE FLINT HILLS DIVISION.
This division of the Big Blue series takes its name
from the great monoclinal ridge, called the Flint hills,
that extends from the northern part of the Osage Nation
northward along the eastern border of Cowley and But¬
ler counties, Kansas, its rocks forming an important part
of the ridge and the highlands that constitute in Chase,
Morris, Riley and other counties, its dissected northern
and northeastern extension. Of these "Permian mount-
THE PERMIAN SYSTEM IN KANSAS.
7
ains" as the Flint, hills were called by Prof. Broadhead
in his geological studies of eastern Kansas,* the rocks of
the Flint Hills division occupy the summits, a narrow up¬
per zone of the steep eastern slope, and all of the gentler
western slope, extending westward along the south line
of the State to the Arkansas river. In the brow of the
bluffs of the latter river and its affluent, Walnut creek, at
Arkansas City, certain limestones charged with Athyris
subtilita Hall, Derby a crassa M. and H.?"!* Productus semi-
reticulatus Martin, Septopora biserialis Swallow, Schizodus
wheeleri Swallow (?), spines of Archeeocidaris, fragments of
small crinoid-stems, and other fossils characteristic of the
division, being the highest horizons that present a largely
brachiopod fauna of Carboniferous affinities, approximately
mark the summit of the division. Stratigraphically, the
Flint Hills division includes the true Permo-Carboniferous
rocks of Kansas, or more definitely, the Neosho and Chase
formations of Prof. Prosser's recent paper, "The Classifica¬
tion of the Upper Palaeozoic rocks of Central Kansas.";};
The Neosho formation consists chiefly of shales, with
some limestones which are for the most part of no great
thickness, and frequently marly.
The Chase consists also partly of shales, but is more
conspicuous for its massive limestones, which include three
flint-bearing limestones, or so-called flints, that have been
named, in ascending order, the Wreford, (JAay), the Florence
(Prosser), and the Marion (Prosser).
Prof. Prosser, the most recent authority on the Car¬
boniferous and Permian paleontology of Kansas, lists from
*'J'he Carboniferous Rocks of Southeast Kansas. Am. Jour. Sol.,
Vol. XXI, pp. 55-57; 1881,—and. Carboniferous Rocks of Eastern Kan¬
sas. Tran. St. Louis Acad., Sci., Vol. IV, Part 3, pp 481-492; 1884.
'\Derbya multisWiata M. and H. ?
JCharles S. Prosser, Journal of Geology, Vol. Ill, No. 6, pp.
682-70.5, and No. 7, pp. 764-800. See latter No., pp. 764-786 and pp.
797-800. October November, 1895.
8
COLORADO COLLEGE STUDIES.
the Neosho and Chase formations the following fossils,
which doubtless constitute the greater part of the
FAUNA OF THE FLINT HILLS DIVISION.
*Chsetetes carbonarius Worthen.
'fChseletes sp.
*Zaphrentis Bp.
t*Crinoid stems.
"fArchseoddaris plates and spines.
lEchinoid spine.
*Spirorbis sp.
"fSpirortia orbiculostoma Swallow.
"fSpirorbis cf. permianus King.
"fPolypora submarginata Meek.
'\*Septopora biserialis Swall. .
fFeneslella ahumardi Prout.
"f*Rhombopora lepidodendroidea Mk.
'\*Aihyria aubiilila Hall.
'\*Chonetea granulifera Owen.
■\*Produclua aemireticulatua Martin.
tSame, var. calliounianua Swall.
'\Productua coatatua Sowerby.
i'*Productua nebraacenaia Owen.
■\*Derbya craaaa M. and H.
"fDerbya muUistriata M. and H.
'\*Meekella atriato-coatata Cox.
'\Meekella (?) ahumardiana Swall.
'\Entelelea hemiplicaiua Hall.
"fSpirifera plano-convexa Shumard-
'\*Pinna peracvda Shum.
^Avicalopecten carboniferua Stevens
"fAviculopecten maccoyi M. and H.
'f*Aviculopecten oceidentalia Shum.
'\*Paeudomonotia hawni M. and H.
*Same, var. ova'a M. and H.
*Pkurophorm oblongua Mk.
*Pleurophorua aubcoalaiua M. and
W.
Pleuroplwrus aubcuneatua M. and
H.
■\*Myalina perattenmta M. and H.
■f*Myalina kanaaaenaia Shum.
*Myalina awallovi McChesney.
'\Myalina recurviroatria M. and W.
(?)
'\Edmondia calhouni M. and H.
*Edmondia cf. nebraacenaia Geinitz
'f*Alloriama aubcuneaia M. and H.
*Schizodua cf. curtiforme Walcott.
"fScMzodua cf. wheeleri Swall.
fMacrodon aangamonenaia Worth.
'\Bakevellia parva M. and H.
]Chvenornya minnehaha Swall.
fSedgwickia altiroatrata M. and H.
tStructure like Stylolites.
*Diacina sp.
*AcUa robuata, Stevens.
f*Aclia awalloviana Geinitz.
*Bellerophon cf. aublxvia Hall.
*BeneTophon cf. montfortianua N.
and P.
*MacrocMl'ma angulifera White(?)
t(?) Ghtuconome sp.
t(?) Orthonema sp.
fStraparoUua aubquadratua M. and
W.
fStraparoUua aubrugoava M. and
W.
^StraparoUua cf.pemodoaua'M.. and
W.
tOf. Loxonema geinitziana King.
fNaiitihia eccentricua M. and H.
\Phillipaia aangamonenaia M. and
W.
In this list the asterisk denotes occurrence in the Ne¬
osho formation, and the dagger denotes occurrence in the
Chase.
For details of the stratigraphy and paleontology of the
THE PERMIAN SYSTEM IN KANSAS.
9
division, reference should be made to the account of the
Neosho and Chase formations in Professor Prosser's paper
above cited.
Reptilian foot-prints are said to have been found on
flagstone of this division (in the Chase formation) at
Winfleld.*
THE SUMNER DIVISION.
Succeeding the Flint Hills division is the Sumner.
The rocks of this division are largely shales. The lime¬
stones are thinner, less frequent, and more impure than
those of the Flint Hills division, and as they pass more and-
more deeply below the surface to the westward, they give
place gradually and at length almost wholly to argillaceous
shales and rock-salt. The division includes many local
beds of gypsum and some of dolomite.
The records of the prospector's drill show for the
Sumner division a thickness of about 600 feet at Caldwell
and of about 800 at Anthony.
In this division, just before the disappearance of all
fossils from the Paleozoic rocks of Kansas, a strictly
Permian fauna makes its appearance.
THE GEUDA SALT MEASURES.
In the vicinity of Arkansas City, the southwesterly-
dipping, brachiopod-charged limestones and shales of the
Chase formation disappear beneath a salt-bearing formation
of great commercial importance.
The Permian rocks of Kansas and Oklahoma include
two extensive rock-salt-bearing formations, the lower and
the upper salt-measures, belonging, one in the Big Blue,
*The proprietor of one of the quarries at Winfleld once informed
the writer that, in^quarrying flagstone for paving, his workmen re¬
moved a large slab covered with reptilian footprints. The slab was
cut into pavement-blocks and shipped, contrary to orders, and so lost
sight of, it having been the owner's intention to preserve it in the
interest of science.
lo COLORADO COLLEGE STUDIES.
and the other in the Cimarron series. Elsewhere in this
article, the upper formation is described as the Salt Plain
measures; the lower formation, which is the basis of the
great salt industry of Kansas, is here called the Geuda salt-
measures, from the town of Geuda Springs, which is located
in the area of its outcrop.
At a quarry to which the writer was conducted by the
favor of Prof. A. W. Jones of Salina, and which is near the
right bank of the Smoky Hill river two or three miles
S. S. E. of Salina, is an exposure ef perhaps about 30 feet
of carbonaceous shales and more or less shaly limestones
having rather a pronounced westerly dip and including a
fossiliferous horizon in which one lamina of rather hard
limestone bears numetous indifferently preserved examples
of Myalina permiana and smaller undetermined bivalves.
This ledge is apparently but little below the summit of the
Geuda and overlies a bed of gypsum, which {fide A. W. J.)
outcrops in the bed of the river near by and is also pierced
by a shallow shaft in the vicinity of the quarry. Prof.
Jones states that the most southerly appearance of these
limestones and shales on the Smoky is about four and a
half miles south of Salina. He also states that the gypsum
at this quarry is supposed to be the same as that which is
worked at Gypsum City; but it seems to the writer, from a
consideration of the dip of that gypsum between Hope and
Gypsum City, that the gypsum south of Salina, which may
be called the Greeley gypsum from its occurrence in Greeley
township, is higher by not less than a hundred feet than the
Hope gypsum, as that at Hope and Gypsum City may be
called.
The lower limit of the Geuda in north-central Kansas
is drawn at the summit of the Marion concretionary lime¬
stone of Prof. Prosser, which the latter seems with good
reason to regard as the "first cherty limestone" of Prof.
Swallow.
The Geuda formation is very complex in its com-
THE PERMIAN SYSTEM IN KANSAS.
II
position. It consists primarily of clay-shales, but these
are of many colors and sorts, frequently passing into saline,
gypseous, and calcareous varieties, or even giving place to
limestone, gypsum, or rock-salt. The composition of the
formation in and near its area of outcrop is quite different
from that revealed by the drill in deep-lying parts remote
from that area.
Its area of outcrop, doubtless somewhat narrowed
by the leaching out of rock-salt and the settling of sup¬
erincumbent strata, is in part occupied by a belt of
more or less gypseous and saline shales interspersed with
beds of massive gypsum and impure limestone, and
which has as additional manifestations of its mineralized
character, occasional salt-marshes, saline springs, bitter
waters, and wells which (where not dug in the superficial
deposits of the Neocene) are not infrequently brackish or
saline. Near the south line of Kansas, this belt occupies a
breadth of some 12 to 18 miles in adjoining portions of
Sumner and Cowley counties, the greater portion of which
is in Sumner, and with variable breadth extends thence nearly
northward through the eastern parts of Sedgwick, Harvey,
McPherson and Saline counties, and western parts of Mar¬
ion and Dickinson, to the region between Salina and Hope,
from which region it continues in a nearly northeasterly
course through portions of Clay, Riley, Washington and
Marshall counties. The so-called "Wellington marble,"
described by the writer in 1885,* and which comes from
the eastern part of Sumner county, and the gypsum used
in the manufacture of plaster of Paris, stucco, and cement
in Dickinson and Marshall counties, as well as many unused
beds of gypsum, belong to this belt. There are, however,
in the belt at least two distinct horizons of gypsum, and it
is the lower, or Hope, gypsum, that has been hitherto most
used in the nftinufacture of plaster of Paris. The salt-
*Bulletin of the Washburn College Laboratory of Natural His¬
tory, No. 3, page 87.
12
COLORADO COLLEGE STUDIES.
springs and salt-marshes at and north of Geuda Springs in
Sumner county, and southwest of Arkansas City in Cowley
county, are also within this belt. Various geographic
names in this belt have been taken from its geological
peculiarities. Thus there are several streams called Gyp¬
sum creek, a Gypsum township, and even a Gypsum City;
the two Slate creeks of Sumner county take their name
from slate-colored shales which belong, in the case of the
larger stream partly and in the case of the smaller one
wholly, to the Geuda measures; Bitter creek, in adjoining
parts of Sumner county, Kansas, and K county, Oklahoma,
and intermediately the Bitter Creek postofiice, Geuda
Springs, and its now abandoned neighbor. Salt City, are all
named or, in the case of Geuda Springs, best known from
peculiarities of these measures. At Geuda Springs, are
several mineral springs differing in the analyses of their
several waters, but all belonging to the saline class. These
and the salt-marsh of the same locality and the beds of
gypsum and limestone not far away, present a fair epitome
of the characteristics of the Geuda outcrop.
The shales of the Geuda outcrop are blue, gray, slate-
colored, drab, buff, red and various shades of bluish and
brownish red. In the deepest known parts ef the Geuda
the three first-named colors prevail.
The limestones of the Geuda are in part unfossilferous,
but those in the lower and sometimes those in the upper
part of the formation contain a fauna from which
brachiopods and essentially Carboniferous fossils are
all but wholly excluded, and which, indeed, consists
almost entirely of Lamellibranchia of recognized Per¬
mian affinities. The writer has personally identified
only a few of the fossils of these limestones, and some
of the determinations recorded by the earlier writers on
this part of the Kansas section have need of verification or
require revision of synonymy. We therefore present here
the list of fossils recently recorded from these limestones by
THE PERMIAN SYSTEM IN KANSAS.
13
Prof. Prosser,* as embracing a substantial part of the
FA VNA OF THE GEUDA MEASURES.
Septopora buerialis Swallow. Bakevellia parva M. &H.
Derbya muUistriata M. & H. Schizodus curtus M. & W.
Pseudomonotis hawni M. & H. Schizodus ovatus M & H.
Same, var. ovata M. & H. Nuculana bellistriata Stevens, var.
Pseudomonotis cf. variabilis Swall. attenuata Meek.
Myalinapermiana Swall. Nucula cf. beyrichi Scbauroth.
Yoldia subicitula M. & H. Nucula cf. parva McChesney.
Aviculopecten occidentalis Shumard. Dentalium meekianum Geinitz.
Pleurophorus subeostatus M. & W. Macrochilina cf. angulifera White.
Pleurophorus subcuneaius M. & H. Cf. Aclis swaUoviana Geinitz.
Edmondia calhouni M. & H. Nautilus eccentricus M. & H.
Observations recorded by Messrs. Swallow and Hawn
and Meek and Hayden in northern Kansas, and others made
by the writer in southern Kansas, indicate that Athyris
subtilita and several other Carboniferous species of fossils
may occasionally range up into the basal part of the Geuda;
but the fossils thus referred to should perhaps be regarded
as more or less varietal representatives of their types.
Several years ago, Mr. E. F. Osborne informed the
writer of an early discovery of reptilian footprints near
Salina in rocks which must be referred to this division.
About four miles east of Salina, at a point about half a mile
south of the Smoky Hill river and west of north of Iron
mound, is an abandoned quarry. The upper stratum is a
ten-inch ledge of so-called "bastard limestone" that was
used by the settlers in the earlier days of Salina's history
for walling wells, etc.f It is upon this stratum that the
footprints were found. It is possible that the reptilian
footprints discovered many years ago by Prof. Mudge on
rocks of the bluffs of the Republican river in northern Kan¬
sas should also be referred to this formation.
Fragments of a charcoal-like sort of fossil wood that oc¬
cur in the salt mines at Kingman, in rock-salt-bearing shale
*Loc. cit., pages 787 and 788.
tWells on the old Osborne place and on the Snyder place were
walled with this stone, and some of the stone probably remains in foun¬
dations of old buildings in the vicinity.
14
COLORADO COLLEGE STUDIES.
above the main beds of rock-salt, are the only vestiges of
plant-life known by the writer to have been found in the
Geuda measures.
In the limestones of the Geuda, geodes of celestite are
frequent.
Traced by the prospector's drill-records away from its
outcrop to its deepest known extensions, the Geuda grad¬
ually changes its composition, the variegated shales and
the gypsum and limestone gradually disappearing and their
place being taken at first partly and at length wholly by
more decidedly saliferous shales of almost constantly blue-
gray to slate-color and massive beds of more or less nearly
pure rock-salt, which constitute the "salt-measures" of cur¬
rent parlance. It is rot positively known that these salt-
measures everywhere come, in their entire thickness, with¬
in limits that correspond with those of the Geuda outcrop;
but their dip and po.sition with reference to higher and lower
formations are such as to indicate their substantial equiva¬
lency to part or (as in the case of Anthony, at least) to
practically all of that outcrop. The gradual disappearance of
limestones and gypsum with depth, implies a progressive
change of physico-geographic conditions in the region be¬
tween the outcrop and the deep parts of the Geuda, showing
that the leaching out of the salt in and near the outcrop—to
the probability of which Prof. Hay has called attention in his
"Geology of Kansas Salt" and elsewhere—is not the sole
(though doubtless a partial) cause of the comparative ab¬
sence of salt from the Geuda outcrop, and that this absence
is partly due to local differences in the physical conditions
under which the Geuda sediments were originally laid down.
The salt is present in every grade of occurrence from
that of minute particles impregnating the shale, through
that of rock-salt and shale intermingled in about equal pro¬
portion, to that of massive beds in which cla}' appears only
as sparsely scattered flecks. As may be inferred from
what has been already said, the proportion of salt in the
THE PERMIAN SYSTEM IN KANSAS. 15
shale and the number and thickness of the rock-salt beds
increase with distance from the outcrop.
In strata of shale associated with some of the principal
beds of rock-salt, occur iron-red pseudomorphs of halite
after selenite.
In the deep-lying part of the formation, remote from
the outcrop, the greatest known thickness of these salt-meas¬
ures is 420 feet, which was obtained in a boring at Anthony.
The thickness of the outcrops probably varies from 300 to
400 feet.
The dip of the Geuda measures in southern Kansas is
southward and westward; in northern Kansas, it appears
from various observations to be northward and westward.
From these data it may be inferred that the salt has the form
of an anticlinal whose summit-line dips nearly westward. It
seems probable that Arlington is located somewhere nearly
over the crest of this anticlinal, since the salt-beds de¬
cline in either direction (northward and southward) from
their position beneath that town. The northward descent
is, however, small as compared with that to the southward.
Thus, at Arlington, the summit of the salt-beds is
reached at an elevation of approximately 910 feet above
sea-level,whence it descends (gradually,as shown by the Ster¬
ling and Lyons drillings) to about 815 feet above sea-level
at Ellsworth and to only about 383 feet above sea-level at
Anthony.
The name here given to this formation is one that has
been applied to it in the writer's manuscripts for many
months. In a reccent article,* Professor Prosser has called
nearly the same formation "the Marion formation;" but
aside from the fact that he includes in such formation a
zone of "variously colored shales and marls" which is
above the zone of gypsum-horizons, and therefore belongs
to the lower Wellington, the name, Marion, as a strati-
graphic term, is preoccupied, having been previously es-
*Loc. cit., p. 786.
16 COLORADO COLLEGE STUDIES.
tablished by Professor Prosser in the same article for
another quite different stratigraphic value, the Marion flint
and concretionary limestone, a member of the Chase forma¬
tion.*
THE WELLINGTON SHALES.
It has been established by numerous borings in the
region underlaid by rock-salt in Kansas that there is above
the salt-measures a body of clay-shales with a thickness
of 250 to nearly 450 feet, and having for the most part the
same and darker and lighter shades of the bluish-gray
color that prevails in the clays of the rock-salt deposits
themselves. This fact, though here stated from the
writer's early and independent observations, was recognized
by the late Prof. Robert Hay, who called this zone "the
gray shales" and "the gray beds,"f apparently in contrast
with the "red-beds" of the Cimarron series. It is for this
zone of gray beds, which must be distinguished strati-
graphically from the underlying and similar gray beds of
clay-shale in the Geuda salt-measures, and which is not
everywhere gray through its entire thickness, that the
formational name, Wellington shales, is here proposed.
These shales are thicker in southern than in northern
Kansas, attaining their greatest known development be¬
neath the town of Caldwell, where the drill has shown them
to have a thickness of 445 feet. They contain satin-spar
veins and infrequent and limited saline impregnations, but
no rock-salt. Within the area of their outcrop and as
reached by borings near it, as respectively at Wellington
and Caldwell, the Wellington formation often includes beds
of impure limestone and calcareous shales and occasional
beds of gypsum and dolomite.
Beneath Ellsworth, the Wellington is 255 feet thick
*Loc. cit., p. 772.
tGeology of Kansas Salt. Seventh Biennial Report of the Kansas
State Board of Agriculture, Part II, pp. 83 to 96.1891. (See page 87.)
THE PERMIAN SYSTEM IN KANSAS.
17
and has a 20-foot zone of red shale 60 feet below its sum¬
mit. Of the 395 feet of Wellington pierced by the drill at
Anthony, 365 feet is the typical blue shale, the remaining
30 feet being a nearly basal zone of red shale.*
At Wellington itself, from which, as a locality within
the area of its outcrop, the formation is named, and in
whose vicinity are exposed some of the shales that have
suggested the term "gray beds," and, together with similar
shales of the Geuda, have given provincial but not very
accurate name to the Big Slate creek of Sumner county, a
considerable part of the more than two hundred feet of
shale passed through by the drill before reaching the rock-
salt, is alternately red and greenish (or bluish) gray.'j-
This red and gray mottled and banded character appears
also in the lower Wellington shale that outcrops in central
and western parts of McPherson county and at intervals in
the foot of the bluffs of Spring creek from Salina to a point
in the southwest vicinity of Bavaria, occupying in the latter
situation the interval between the Mentor beds and the zone
of shale, gypsum, and Mj'alina-bearing shaly limestone that
forms the summit of the Geuda along the Smoky Hill river
south of Salina. But while the red colors so prevalent in
the rocks of the Cimarron series, invade the gray in certain
quarters of the Wellington, they affect but a small pro¬
portion of the whole, and the Wellington is, notwith¬
standing these and its calcareous inclusions, essentially a
thick body of blue-gray and slate-colored shales.;};
The massive ledge of hard, cellular, gray dolomite on
the Little Arkansas river at the eastern border of Rice
*Only 25 feet of the blue shale intervenes between this red zone
and the summit of the rock-salt.
fThis statement of the drill-record at Wellington is made on the
authority of Mr. E. W. Davis, driller.
JAt Pratt, salt has been found in drilling without first passing
through any large body of blue-gray shales such as must be pierced to
reach the salt at Hutchinson, Kingman, Anthony, etc.; but, as else¬
where indicated, the salt that was there so reached does not belong to
the Geuda. (On a succeeding page, see account of the Salt Plain
measures.)
i8
COLORADO COLLEGE STUDIES.
county, west o£ south from Windom, is provisionally
referred to the Wellington formation.
THE CIMARRON SERIES.
With the Wellington formation, ends the Big Blue, lower,
or limestone-bearing, series of the Permian. Succeeding it
without break, but possibly with a gradually introduced an¬
gular unconformity, are the Harper sandstones and higher
prevailingly red formations that comprise the remainder of
the Kansas Permian, and constitute the- Cimarron series,
which, for Kansas, is nearly the same as the "red beds."*
So far as known, the series is destitute of any trace of
organic remains.
THE SALT FORK DIVISION.
The Salt Fork division is so named because all of its
formations are found within the drainage-basin of the Salt
fork. It includes the Harper, Salt Plain, Cedar Hills,
Flower-pot, and Cave Creek formations, and has a maxi¬
mum thickness of about i,ooo feet.
THE HARPER SANDSTONES.
These constitute the lowest and thickest formation of
the Cimarron series. They comprise several hundred feet
of more or less mottled, but prevailingly dull-red, or brown¬
ish-red, argillaceous and arenaceous shales and sandstones,
above the Wellington shales and below the Salt Plain
measures. The word, sandstones, as applied to this for¬
mation, is intended to imply, not that its rocks consist
mainly of sandstone throughout their thickness, but that the
frequent low ledges of rock which accentuate the forma¬
tion are of sandstone. Much of the latter is of the sort
quarried at Harper—a reddish-brown or roan-colored sand¬
stone, sometimes mottled and streaked, soft enough to be
easily quarried and dressed, but becoming harder by seas-
*Some authors, however, may have included the limestone-bear¬
ing Wellington and possibly even the rock-salt-bearing Geuda in their
use of the term "red-beds," as applied to Kansas rocks
THE PERMIAN SYSTEM IN KANSAS. 19
oning, and constituting an excellent dimension-stone. As
this stone first became well known as a building-material
from its use at Harper, and as the outcrops of the forma¬
tion which includes it occupy a large portion of Harper
county, the name. Harper, seems doubly appropriate for
the formation. The term. Harper beds, may be found more
convenient, in some cases, in referring to the formation,
than that of Harper sandstones.
As one travels westward from Wellington, the red
shales and sandstones of the Harper outcrop are first met
with near Milan. They occur thence westward to the
vicinity of Sharon; but in their western extent are seen
only in the lower parts of the country. They occur on
middle regions of the two Ninnescahs and of the Chikaskia
river. On Bluff creek the sandstone has been largely
quarried and employed for business buildings at Anthony,
where the Bennett House and the Anthony Roller Mills,
both three-story buildings, are constructed of it, and where,
as at Harper, it has given excellent satisfaction. Similar
stone, most if not all of which belongs to the Harper forma¬
tion, is used from quarries in the vicinity of Kiowa, Hazel-
ton, Attica, Milan, Spivey, Arlington, and other towns of
this region.,
No observations have yet been made as to the dip of
the Harper sandstones. The prospector's drill has shown
that the Wellington shales and the rock-salt-bearing hor¬
izons of the Geuda, in a considerable part of southern
Kansas, descend and thicken both southward and from
their outcrop westward. While the same can not be as¬
serted of the Harper, certain similar facts are known of
the latter also. Thus, we find that the base of the Harper
descends to the southward and to the westward within cer¬
tain known limits* The base of its outcrop at Caldwell is a
rough hundred feet lower than it is some fifteen miles
further north, in the eastern neighborhood of Milan; and at
Anthony, some" twenty-five miles west of the Caldwell-
20
COLORADO COLLEGE STUDIES.
Milan base-line, the base, as reached by the drill, is appar¬
ently some 300 feet lower than at Caldwell. Taking the
latter town as the base and Sharon or Attica as the approx¬
imate summit of the Harper beds, and making no allowance
for dip, the difference of elevation of these places would
. give about 350 feet as the thickness of the Harper, a figure
that would be reduced to about 250 feet, if the base as out¬
cropping near Milan be taken as bench-mark. But that
dip or accession of sediments westward, or both, must be
reckoned with, is indicated by the fact that at Anthony,
which is at least 100 feet below the summit of the forma¬
tion, (and where the Sumner division has at least its full
average thickness), the prospector's drill descended about
550 feet before reaching the apparent summit of the Well¬
ington, making the thickness of the Harper, as thus meas¬
ured, about 650 feet.
Carbonate of copper, including both azurite and mala¬
chite, occurs in the Harper formation, chiefly as stain in
calcareous shales in the basal part of the formation* (as at
Caldwell) and more rarely in sandstone concretions at higher
horizons (as west of Harper); but the occurrences are lim¬
ited and promise nothing of value from a mining point of
view.
Some of the earthy brownish-red and gray shales of
the Harper formation, occurring a short distance east of
Kingman, form the basis of the "Cherokee Brown Mineral"
and "Silver Gray" manufactured by the Kingman Paint
Company, and which has had considerable demand in the
paint-trade of Topeka, Kansas Cit}'^ and other markets.
THE SALT PLAIN MEASURES.
Occupying an interval between the Harper and the
Cedar Hills sandstones, in southern Kansas and northern
Oklahoma, is a zone of red shales (? with some sand-
*Really in transitional beds which might perhaps be reckoned
equally well as constituting the summit of the Wellington.
THE PERMIAN SYSTEM IN KANSAS. 21
stones) in which saline impregnations are common, giving
rise to salt springs, salt creeks, salt or brackish wells and
other saline waters within and near the area of their out¬
crop, and resulting in a topography characterized by vari¬
ous closely allied features termed salt-plains, salt-marshes,
salt-draws, salt-bars, salt-licks, salines, etc., in which the
chloride of sodium is often practically pure, but sometimes
associated with other salts.
These salt-impregnated shales constitute what may be
regarded as upper, or secondary salt-measures. Compara¬
tively little use has been made of these measures as a salt
supply hitherto, owing to the undeveloped condition of this
part of the country and to the vast supplies of salt found to
the eastward in the Geuda measures. But much use has been
been made of the salt of the Great Salt plain, within distances
to which it can conveniently be hauled in wagons, as in dry
seasons it forms on the "plain" a crust of pure, coarsely
crystallized salt several inches in thickness, which is easily
removed and available, as taken, for " stock-salt" or, with
simple crushing, for all of the domestic uses to which salt
is put. This salt-crust is composed in part of pyramidal
and intersecting turkey-foot groups of cubical crystals and,
as viewed from the brow of the bluffs which overlook it,
appears like a field of glistening snow. In the early days
of the settlement of western Kansas, the salt was hauled
over the old Nescatunga, or Kinsley, trail to Kinsley and
other points on the A. T. & S. F. railway. Salt derived
from the Salt Plain measures is now manufactured at
one point, if not more, in Oklahoma, in which common¬
wealth it is probable that these upper measures will ulti¬
mately become of considerable commercial importance.
Rock-salt is alleged to crop out in a ravine near the Salt
plain ;* but no examination as to the accuracy of this report
has been made.*
*0n the north side of the Cimarron, in a canyon a few miles below
the entrance of Buffalo creek.
22
COLORADO COLLEGE STUDIES.
As local saline impregnations occur to some extent in
most of the terranes of the Kansas-Oklahoma Permian,
it is possible that it may not always be easy to distinguish
the limits of the Salt Plain measures; but the salt-zone
which is here especially designated as the Salt Plain meas¬
ures is of considerable extent and is that from which is de¬
rived the salt of the Salt plain of the Cimarron river
(called often the Great Salt plain), which is the saline usually
referred to in the literature of this region when the un¬
qualified expression, "the Salt plain," is'employed.
The stratigraphic position of this salt-zone may be
seen in Kansas on the east slope of the Cedar hills of
Harper county and on the south side of the Salt fork, a
few miles below .^tna, where, in each case, beginning
immediately below the bright red Cedar Hills sand¬
stones, are the saliferous clay-shales which are the source of
the salt that at the one locality gives character and name to
the Little Salt creek that traverses adjoining parts of Barber
and Harper counties, and at the other has given rise to
one of the peculiar flats, or base-levels, so frequent in salt-
shale topography, and which are evidently produced
through the agency of the salt itself. Little Salt creek,
though having the highest source of its salt in a horizon of
saline impregnation immediately below the base of the Cedar
Hills sandstones, apparently cuts other saline horizons
at somewhat lower levels, and its lower portion may inter-
graduate with and be only arbitrarily separable fiom the
upper of the Harper sandstones.
At Pratt, salt deposits were encountered a few years
since, in drilling, without first passing through any thick
body of gray shales like the Wellington; and the relation of
these to not far distant outcrops of the Cimarron series and
to sea-level, indicates that they belong to the upper, or Salt
Plain, measures.
The following is a condensed record of the boring at
Pratt:
THE PERMIAN SYSTEM IN KANSAS.
23
Thickness. Depth.
Neocene marl, sand and gravel 89 89
Red eandstone and clay, with veins of water at inter¬
vals. (A vein of salt water was cased out at 150 feet) 537 626
Shales, almost wholly red, more or less saline 89 715
Rock-salt, with small admixture of shale 30 745
Salty red and blue shale (mostly red) 13 758
Rock-salt, with small admixture of shale 22 780
Shaly salt gradually becoming red and blue shale 20 800
Red shale with eome blue spots 50 850
Rock-salt, with small admixture of shale 20 870
Dark red shale, blue mottled i.l34 1004
This section affords the only data here available with
which to indicate the thickness of the Salt Plain measures,
giving for the vertical range of the rock-salt 155 feet,
which, with a few feet added for transitional sediments
above and below, probably approximates the thickness of
these measures as developed at and near their outcrops in
Kansas.
On another page of this article it is shown that if a
line be drawn between Ashland and a point about six miles
southwest of Medicine Lodge, the Medicine Lodge gypsum
dips in both directions (more or less nearly southward and
more or less nearly northward) from that line. A similar
relation to about the same line apparently obtains in the
Salt Plain measures, as these certainly dip from about this
line far southward into Oklahoma, and they have an appar¬
ent dip of about 8 feet per mile from the same line to the
latitude of Pratt.
The saline springs on the upper part of Little Mule
creek, in Barber county, Kansas; the great salt spring at
the head of Salt creek in Blaine county, Oklahoma, from
the brine of which several tons of table-salt are now made
daily, and which is said to furnish brine enough for the man¬
ufacture of 160 tons a day; and (with less confidence) the
Salt plain of t]je Salt fork in Woods county, Oklahoma
(sometimes known as the Little Salt plain) are provision¬
ally referred to the Salt Plain measures.
24
COLORADO COLLEGE STUDIES.
THE CEDAR HILLS SANDSTONES.
The Salt Plain measures are succeeded by a zone of
rocks in which unevenly hard, in part massive concretion¬
ary, fine-grained, bright-red sandstones, having some re¬
semblance to those of the Red Bluff terrane of the Kiger
division, constitute the leading feature. This may be seen
a few miles northwest of Hazelton, Kansas, below the
Neocene sands which there form the summit of the Cedar
hills. From this occurrence, the terrane takes its name.
It is finely displayed in the canyon-cut basal incline of the
Gypsum hills, southwest of Medicine Lodge, and in the
same southeast of ^tna. The bright-red sandstone in the
low bluff north of Sharon and that outcropping on the south
fork of the Ninnescah river west of Kingman are provision¬
ally referred to the Cedar Hills formation.
This formation has nowhere been measured. From
memory, it is roughly guessed at 50 to 75 feet as seen in
the basal incline of the Gypsum hills of the Medicine Lodge
river and the Salt fork.
THE FLOWER-POT SHALES.
Next in order above the Cedar Hills sandstones, but
entirely eroded from the summit of the Cedar hills, while
seen in full thickness a little farther west in the escarpments
of the Gypsum hills, southwest of Medicine Lodge, and tak¬
ing their name from the well-known Flower-pot mound
which has been carved out of them by erosion at the point
of the divide between East Cedar and West Cedar creeks,
are the Flower-pot shales. These, for the most part, are
highly gypsiferous clays.
Flower-pot mound has been named by the residents of
Barber county in allusion to the fact that its top is plumed
with several small cedars which, outlined against the sky at
a short distance, present a fancied resemblance to plants
growing from a flower-pot. It is necessary to consider
only the top of the mound to see the flower-pot, since other-
THE PERMIAN SYSTEM IN KANSAS.
25
wise the pot were inverted. But to the geologist, the
flower-pot is the mound itself; for the slopes of the latter,
like most exposures of these clays elsewhere, are strewn
with mineral blossoms of divers colors and constitute a very
respectable geological bouquet. Light-red, dark-red, bluish-
red, pink, greenish-white, bluish-white and gray, mixed in
confusion with red in the ascendancy, give much of the out¬
crop of this terrane a variegated aspect; or as viewed at
some distance, a hue approaching the late fashionable color
known as "crushed strawberry." The surface is often
strewn with fragments of white, pink, red or water-clear
satin-spar flecked with green or red clay, and is sometimes
also setoff with sparkling crystals of selenite. For such a
member of the Salt Fork division, a geological posey-bed
in appearance, the designation, "Flower-pot," seems very
natural, and it is doubtful if a more appropriate name of
local geographic origin could be found.
As seen in canyon walls or other vertical exposures,
the satin-spar forms a network with irregular rhomboidal
meshes. It lies, in fact, in a trestle-work of warped plates
traversing the clay in all directions, but chiefly in oblique
positions tending toward horizontal. The clay is thus in¬
closed, sometimes between tortuous subhorizontal and sub-
parallel seams, sometimes in spacious sublenzitoid compart¬
ments subject to partition in various directions by intersect¬
ing veins. The seams vary from mere paper-seams to
plates several inches in thickness.
A noticeable and picturesque feature of the Flower¬
pot clays is the manner in which their outcrops are carved
by the elements. They are, in fact, a theater of rapid ero¬
sion, and many weird spectacles present themselves in their
relief-forms. In localities where their protective covering
of Medicine Lodge gypsum has been removed by erosion,
as for example, near the head of Little Mule creek and in
the district between Eldred and .^tna, they are frequently
cut into rather steeply sloped faces having that peculiar pat-
26
COLORADO COLLEGE STUDIES.
tern of sculpture that is best designated as cone-and-gully
erosion, consisting of alternate cones (more strictly semi-
cones) and rain-gullies. The cones are sometimes arranged
in a close and remarkably uniform palisade-like series on
the face of a rampart-like or amphitheater-like bluff, and in
such instances are calculated to arrest the attention even of
those most indifferent to natural phenomena. Such a pali¬
sade of cones may conveniently be called a conarium.
When viewed at a moderate distance, it recalls the arrange¬
ment of points on a backgammon-board. Occasionally the
adjacent conaria of two parallel ravines meet, producing a
sharp serriform spur running out upon a base-level of eros¬
ion. An example of the latter sort (doubtless short-lived
in its destiny) is seen near the road from the old Eldred
postoffice to .^tna. On the whole, the outcrop of the
Flower-pot clays, with its conaria and occasional pinnacles
and buttresses, presents a type of erosion similar in many
respects to that of the northern Tertiary "Bad Lands."
Its mineral-surcharged character renders its occasional
smoother tracts little less barren than the ruggeder portions,
so that the Flower-pot lands are generally waste-lands.
From the eastern escarpment of the Gypsum hills
northwestward in the bluffs of the Medicine Lodge river and
its tributaries, the Flower-pot formation may be seen in
diminishing exposures, as it gradually descends below the
river-valley. It disappears under the latter a few miles
below Belvidere. It appears in the divide between East
Cedar and Little Mule creeks; on the upper branches of
the latter; and on the Salt fork drainage, from the Eldred
district on the north and the eastern promontory of the
Cimarron-Salt fork divide on the south, northwestward to
a point above the mouth of Cave creek. It extends up
Big Mule creek at least seven or eight miles from its mouth.
It is well displayed in both bluffs of the Cimarron river at
the Great Salt plain, and thence down that stream to an
unknown distance beyond the bridge of the Panhandle
THE PERMIAN SYSTEM IN KANSAS.
27
branch of the Santa Fe railwa}-. It appears again, if re¬
membered correctly, in the lower part of the bluffs that
border the Beaver on its south side at the locality where
the Panhandle line crosses. It is not seen from that line
on the Canadian, though the sections given by Shumard in
Marcy's Red River Report make it clear that lower down
on the Canadian, and on both forks of Red river as well, a
body of similar clays lies beneath the gypsum.
The thickness of the Flower-pot shales on the Salt
fork, southeast of JEtna, is in the neighborhood of 150 feet.
THE CAVE CREEK FORMATION.
Above the Flower-pot marls is an important gypsum-
bearing formation, consisting usually of either a single
stratum of massive gypsum or two such strata separated by
an interval of red clay-shale. It may be called the Cave
Creek gypsums, or formation, because well displayed in its
fuller development on Cave creek, in Comanche county,
Kansas. The formation appears with a similar tripartite
character on the north branch of Red river, as indicated by
Dr. George G. Shumard on Plate V of Marcy's Red River
Report. The lower gypsum horizon (below named and
described as the Medicine Lodge) is the heavier and
persists throughout the present known extent of the forma¬
tion; while the upper, or Shimer (so named after the town¬
ship through which Cave creek flows), is less constantly
developed as a distinct bed of massive gypsum, not appear¬
ing at all on the valley of the Medicine Lodge river, so far
as observed.
At the only locality at which it has been measured,
viz., on Cave creek at the Comanche cave,* the formation
has a thickness of not less than 50 feet, of which the Medi¬
cine Lodge gypsum occupies a thickness of 25 to 30 feet,
the Shimer gypsum about a third as much, and the interval
*Named and described below, in the account of the Medicine
Lodge gypsum.
28
colorado college studies.
of red clay, the Jenkins clay (named after the former Jenkins
postoffice, near Cave creek), 7 to lo feet.
The Medicine Lodge Gypsum.—While the Shimer
gypsum and the Jenkins clay require merely brief notice
here, the former resembling the Medicine Lodge gypsum
and the latter the commoner gypsiferous red clay-.shales of
the Salt Fork division, the Medicine Lodge gypsum calls
for a special description, on account of its stratigraphic im¬
portance and its more than ordinarily interesting general
character.
If, on the road from Harper to Medicine Lodge, the
traveller finds himself looking westward across the valley
of the Medicine Lodge river on one of those enchanting
days for which southern Kansas yields the palm to no
other locality, the autumn air being tinged with just enough
of haze to purple the remoter vistas of the ruddy landscape,
"The splendor falls on castle walls "
which rear themselves seemingly as low mountains or
buttressed escarpments of a table-land crowning the further
incline of the valley and bounding a considerable part of
the western horizon.
These are the Gypsum hills. They are a northern
extension of those on the Red and Canadian rivers, observed
by Marcy in his Red river expedition of 1852 and earlier
reconnaissance, and illustrated in the report of that expedi¬
tion in 1854.
The earliest geological study of the Gypsum hills of
Kansas was made in 1884 by the writer, who gave an
informal description of them before the '84 meeting of the
Kansas Academy of Science at Lawrence, publishing a
sketch of their physical geology a few months later in the
Bulletin of the Washburn College Laboratory of Natural
History.*
*No. 3; published about May 1, 1885.
THE PERMIAN SYSTEM IN KANSAS.
29
As seen at their eastern border about six miles south¬
west o£ Medicine Lodge, the foundations of the Gypsum
hills are laid in Cedar Hills sandstone, their walls are reared
in the variegated sediments of the Flower-pot shales, and
they have, as coping, a massive bed of gypsum to which
the stratigraphic name. Medicine Lodge gypsum, is here
given, in double allusion to its overlooking the valley of the
Medicine Lodge river for many miles and to its prominent
position opposite the picturesque county-seat of Medicine
Lodge, in which was established the first mill to make large
commercial use of this gypsum.
For a considerable distance along the Medicine Lodge
river, the Salt fork. Big Mule creek, and the Cimarron
river, the outcrop of the Medicine Lodge gypsum is promi¬
nent and practically continuous. It is usually best displayed
on the south side, owing to the fact that here, as generally
on the Plains, easterly-flowing streams, while planing down
to base-level, are shifting to the south, their valleys conse¬
quently having a short and steep slope with bold bluffs and
deep canyons as prevailing topographic features on the
south side, and a long, more or less alluvium-laden slope
with less rugged relief on the north. The Medicine Lodge
gypsum, however, is itself conducive to rugged surface-
features, and even on the north side of these streams the
exposures of the gypsum are sometimes conspicuous. The
best of these north-side exposures are seen on southward-
running branches, such as Mulberry creek of the Medicine
Lodge river drainage east of Sun City, and Cave creek of
the Salt fork drainage west of Evansville.
The Medicine Lodge gypsum is seen on the Medicine
Lodge river from the eastern border of the Gypsum hills
to a point about four miles southeast of Belvidere, where it
disappears beneath the Dog Creek and Red Bluff formations
of the Kiger division in the floor of the river-valley. On
the Salt fork, it extends from the eastern extremity of the
high bluffs capped by it a few miles southeast of u®tna.
30
COLORADO COLLEGE STUDIES.
westward beyond Cave creek, and to a limit not observed
by the writer, but stated by Prof. St. John to be at "Cotton¬
wood creek". On the Cimarron river it forms the brow
of the bluffs along the south side of the river at the bridge
of the Panhandle branch of the A. T. & S. F. railway and
e.xtends thence to the southeastern part of Clark county,
Kansas. At Ashland, in the latter county, clay-charged
gypsum, probably representing this or the Shimer hori¬
zon, was pierced in a well at a depth of about 125 feet
by Dr. W. J. Workman. The outcrop of the Medicine
Lodge gypsum on the Cimarron river has not been ex¬
plored by the writer below West creek in the western edge
of Woods county, Oklahoma; but according to Mr. H. C.
Chapman, Editor of the Okeene Eagle, it gradually recedes
from the river south of the Glass mountains, passing the
head of Salt creek in Blaine county, where it is tunneled
into a remarkable park-like system of natural bridges, and
thence extends southeastward to Darlington (a few miles
from El Reno), on the North Canadian. On the latter
stream the greater portion of the outcrop of this gypsum
is doubtless east of the crossing of the Panhandle line, but
a few miles southeast of Beaver City there is a bed of gyp¬
sum which may belong to either of the Cave Creek hori¬
zons or to a higher one. A section of this bed on lower
Clear creek presents a lenticular outline, and the weathered
rocks at the foot of the bluff contain salmon-colored nodules
in a whitish ground-mass, like plums in a pudding, a
feature which is only a phase of the mottled or semi-crys¬
talline character seen in the Medicine Lodge gypsum on
the Cimarron and elsewhere.
The principal stratum of gypsum described and illus¬
trated in their Red River Report by Capt. Marcy and Dr.
Shumard as occurring on the Canadian and on the forks of
the Red river, can scarcely be other than the Medicine
Lodge gypsum.
North of the river of its name, the Medicine Lodge
THE PERMIAN SYSTEM IN KANSAS.
31
horizon has not been identified. Gypsum is said to occur
in Stafford county, Kansas; but this may refer partly or
wholly to the so-called "native lime" of the fresh-water Ter¬
tiary, which also passes under the misnomer of "gypsum"
in western Kansas.
The full thickness of the Medicine Lodge gypsum is
not always shown at the immediate outcrop, owing to the
solvent effect of meteoric water upon it. On the .Medicine
Lodge river it is usually between 12 and 25 feet thick. On
the Cimarron and Salt fork it is considerably thicker. On
Cave creek, a small tributar}' of the latter stream near
Evansville, it has a thickness of 25 to 30 feet.
The prevailing dip of the Medicine Lodge gypsum in
northern Oklahoma and an adjacent strip of Kansas is
nearly south, apparently a little east of south; but a small
area at the north seems to dip in a northerly direction.
This attitude of the stratum may readily be seen by a com¬
parison of its elevations at a few leading points. The ele¬
vations of the summit of the gypsum referred to sea-level
at the points here selected are more or less nearly as fol¬
lows; (A) at Ashland, as indicated in Dr. Workman's
well,* 1840 feet; (B) at point of disappearance of the gyp¬
sum in floor of the Medicine Lodge river valley, about four
miles southeast of Belvidere, 1744 feet; (M) at brow of the
wall of the mesa-like hills between the Medicine Lodge
river and East Cedar creek, southwest of Medicine Lodge,
1800 feet; (H) at Heman station, Oklahoma, near the Cim¬
arron river bridge of the Panhandle branch of the A. T. &
S. F. railway (roughly) 1500 feet; (G) at disappearance of
gypsum below valley of Big Mule creek near the former
post office of Gallagher, a point not far from the intersec¬
tion of the lines AM and BH (and which may here be con-
*The gypsum IJjat was encountered at this depth in Dr. Work¬
man's well may possibly represent the Shimer horizon; hut as no
other zone of gypsum was mentioned as having been met with in the
deeper part of this well, it is inferred that it was the Medicine Lodge,
and that the Shimer bed was not there developed.
32
COLORADO COLLEGE STUDIES.
sidered as coinciding with it), 1812 feet. From these ele¬
vations we find, in the direction from A to M, a dip of 40
feet in 61 miles, or only about ^ of a foot to the mile;from
G to H, one of 312 feet in 48 miles, or 6.5 feet per mile; ffom
A to H, one of 340 feet in 67 miles, or about 5 feet per mile;
from M to H, one of 300 feet in 50 miles, or 6 feet per
mile; from G to B, one of 68 feet in 14.5 miles, or about 4.7
feet per mile; from A to B, one of 96 feet in 46 miles, or
2.1 feet per mile; and from M to B, one of 56 feet in 22.3
miles, or 2.5 feet per mile, the distances, like the elevations,
being subject to some correction, but sufficiently exact for
our present purpose.
In minor parts, the Medicine Lodge gypsum is nearly
pure white; in others it is suffused with leaden-gray or
dusky-brownish shades; most commonly it is greyish-white,
mottled with feebly defined dark spots. The latter are
generally the expiession of a tendency that existed in the
gypsum, under the original conditions of precipitation, to
form crystals, as is shown by the occurrence of the spots in
every gradation from ill-defined spot-like segregations to
well-formed crystals of selenite. Some of the crystals are
of the common rhomboidal patterns, others are of the
stellar type. Even the perfect crystals present the appear¬
ance of dark spots, as transparent inclusions in an opaque
white matrix (comparable with cavities in such a matrix)
would naturally appear. Distinct crystals are far more
abundant in the gypsum on the Salt fork and Cimarron
river than on the Medicine Lodge.
The uneven color and more or less saccharoidal tex¬
ture of the Medicine Lodge gypsum give to its freshly ex¬
posed surfaces, as seen in the quarries of Barber county, an
aspect not unlike that of marble, and the resemblance to
marble is further increased by the fact that the gypsum
takes a fine polish. Hence originated the erroneous names,
"Sun City marble," "Kansas onyx," etc., that have some¬
times been applied to this gypsum.
THE PERMIAN SYSTEM IN KANSAS.
33
With a strength due to the character of its consolida¬
tion and to its massiveness, the Medicine Lodge gypsum
combines the weakness due to its solubility. Owing to
that strength, it is among its fellow-terranes a piece de resist¬
ance, and is, like the Loup Fork sandstone, responsible for
some of the highest bluffs and deepest canyons seen in the
central portion of the Plains. Owing to that weakness, it
is essentially a cave formation. Indeed the gypsum in some
localities is fairly hone)'^combed with earth-filled or empty
galleries and spaces.
Its caves are formed in two ways, and may accordingly
be classified as rift-caves and arch-caves.
The gypsum is parted into large blocks by vertical
master-joints which often persist for long distances, and
which become the conduits of meteoric waters. Enlarged
at first by solution and later perhaps in part by mechanical
erosion, the joint-fissure becomes a narrow and at length
somewhat wider gallery, or rift-cave. It may remain open
or, if it come to be traversed by an intermittent or variable
current carrying sediment, it may become wholly or partly
filled with the latter, and so be either a potential cave or an
actual one with earthen floor, as the case may be.
In forming the arch-caves, water descending through
joints or other crevices in the gypsum, is arrested at the
summit of the Flower-pot shales and finds its way as a vein
along the base of the gypsum, excavating the lower part of
the latter and sometimes also a portion of the underlying
gypsiferous clay by a corrasion in which solution plays the
leading part. In the case of the clay, its fine particles, set
free by the solution of the associated gypsum, may be car¬
ried off by even a feeble current, the readiness with which
these and other red clay sediments of the Cimarron series
are held in mecl\pnical suspension in water being frequently
attested on the Cimarron outcrop by the slow settling of
these sediments in rain-pools.
The rift-cave is doubly typified in what may be called
34 COI.ORADO COLLEGE STUDIES.
Sarcophagus cave, at the Natural bridge on Bear creek, south
of Sun City. This cave has been opened along two
master-joints which intersect at an angle of about 'jo de¬
grees, and it accordingly has two entrances, one about five
rods south, the other immediately north of the Natural
bridge, and neither far above the bed of the creek. In
cross -section, and as well seen at the north eptrance, the
cave has nearly the form of an upright sarcophagus, widen¬
ing gradually upward to a shoulder-region of maximum
breadth, contracting suddenly above the shoulder to a
crested head-part, and narrowing to a simple fissure both
above and below. The present open portion of the cave
extends only from the two entrances to the intersection of
the joint-planes, distances of about 55 and 180 feet from
the north and south entrances respectively; but both gal¬
leries formerly extended in to an unknown distance beyond
this point, the continuation being now filled with compact
cave-earth. It seems probable that the entire cave was
once so filled and that the portion now open was subse¬
quently re-excavated by the water of Bear creek, a portion
of which is diverted from the main channel and traverses
the cave during ordinary freshets. The north gallery has
also an outward extension of its roof for 11 feet in the over¬
hanging wall at its entrance, the lower part of the gypsum
having been here cut away and the cave thus much short¬
ened by the creek's erosion. The breadth of the "Sar¬
cophagus," across shoulders, in this gallery is 4 feet and 8
inches at the entrance, gradually increasing in the inner
half to 7 feet near the junction of the galleries. The height
of this gallery is over 9 feet above the narrow earth-floor
at its entrance and gradually diminishes inward. The south
gallery has a nearly uniform breadth of 4 feet and 6 inches
across shoulders and, containing more earth than the
north gallery, has a broader floor and a height only about
equal to its breadth.
A fine example of an arch-cave is seen on Cave creek.
THE PERMIAN SYSTEM IN KANSAS.
35
a north-side tributary of the Salt fork, not far from Evans-
ville. It is supposed to be the largest of the gypsum-caves
of Kansas, and may be called the Comanche cave, from being
located in Comancbe county.* The east and main entrance
is picturesquely located a short distance back from the
creek in a deep right-hand ravine through which flows a
perennial brooklet of limpid but gypsum-tainted water,
issuing from the cave itself; it is a broadly-arched portal
about 14 feet in height in a wall of gypsum. Near the
latter, and a little south of the entrance, a straight and re¬
markably tall-trunked tree stands sentinel. The cave
covers a little less than 150 yards of the course of the
brooklet, which, from a small gypsum-walled canyon, en¬
ters it through a west portal somewhat like the east one,
but smaller. The cave is slightly sinuous and consists of
three rooms separated by two low arches. The east room
is 14 feet high, 20 to 25 wide, and 123 long. This is fol¬
lowed by an arch, which for 13 feet has a height of only
about 6 feet. The middle room is 12 feet high, 36 wide,
and 50 long, and is lighted in the south side of its roof
through a 6 X 12-foot shaft-like opening that broadens
into a funnel in the high ground above the cave.-j* Through
a second arch, this middle room connects with the west
room, which is lower and much longer than the others and
" is flooded with the waters of the brooklet, here expanded
into a long pool upon which a small boat has sometimes
been used by visitors. The floor of the cave is more or
less strewn with blocks of gypsum that have fallen from
the roof. A bloom of snowy gypsum covers some parts
of the walls and roof, and brown cauliflower-like masses
and concretionary layers of clay-impregnated gypsum are
forming on the floor in shallow pools along the course of
the streamlet. •
*The best railroad-point from which to visit the Comanche cave
is Coldwater, a convenient approach being via Nescatunga and the
John Duckworth place (formerly the post-village of Duckworth).
tTill recently, a cottonwood tree flourished on the slope of this
funnel.
36
COLORADO COLLEGE STUDIES.
A modilication of the arch-cave is seen where a veii
of water reaches an outcrop of the gypsum and of the up
per part of the Flower-pot shales in some ravine and, trick
ling down over the outcrop of the gypseous clays, cause;
the latter to soften and fall away in more or less vertical
sections, excavating a clay-walled room with a gypsum
roof. This may be regarded as a special case of head¬
water erosion, where the excavating done by the streamlel
follows the latter back into a yielding terrane beneath one
that is more resistant, and in so doing changes its work
from that of trenching to that of undermining. A good
example of a cave of this sort is seen in what may be called
the Green room, a cave in the west bluff of Bear creek,
some distance below the Natural bridge and in the imme¬
diate vicinity of an older, partly fallen cave formerly much
visited by picnicking parties from Sun City. It consists of
a single spacious room partly walled up in front by a ridge
of talus from which it is necessary to descend into it as into
a cellar, and is called "the Green room" in allusion to the
fact that its roof is largely incrusted with a beautiful pale-
green layer of stalactitic gypsum studded with capitate pro¬
tuberances like miniature cauliflowers. The latter, formed
by the evaporation of dripping water, are more stipitate
and have a lighter and more open structure than the large
cauliflower-topped masses forming in the pools of the Com¬
anche cave. The color of this roof-crust is only superficial,
however, being due to conditions that favor the culture of
an undetermined alga, supposed to be one of the Cyano-
phycese. The roof of the Green room is traversed by a
channel whose sinuous course marks the former continua¬
tion of the vein that has produced the cave and is still con¬
tinuing it inward.
An interesting topographic feature of the Medicine
Lodge gypsum is its natural bridges. These are merely
remnants of caves that have for the most part fallen in.
Sometimes, as near Havard creek, in Barber county, Kan-
THE PERMIAN SYSTEM IN KANSAS.
37
sas, the same channel may be alternately canyon and tun¬
nel, or bridge.
The best known of these bridges in Kansas is the Nat¬
ural bridge of Bear creek, south of Sun City. This spans
the canyon of the creek, here about 55 feet from wall to
wall. The height of the bridge above the bed of the creek
is at the highest point 47 feet, at lowest 31, and at middle
38. The width of the bridge at middle is 35 feet. The
upper surface of the bridge declines toward the down¬
stream side, but not so much that a wagon drawn by a steady
team could not be driven across it. The thickness of the
arch is therefore greater on the up-stream side, where it
measures 26 feet, than on the down-stream. The relief of
the vicinity seems to indicate that at ^geologically recent time
Bear creek here flowed to the east of its present course and
that its waters, becoming partially diverted by an incipient
cave, enlarged the latter and finally were wholly stolen by
it, the cave at length collapsing save in the portion now
constituting the Natural bridge. Nor is it impossible that
this piracy may be repeated in a minor way by Sarcophagus
cave, which at times already draws a portion of the Bear
creek waters to the west of its proper course.
Reference has been made to a district especially char¬
acterized by natural bridges of the Medicine Lodge gypsum
in Blaine county, Oklahoma. For his knowledge of this, the
writer is indebted to Mr. Chapman. The district is at the
head of Salt creek, a few miles southwest of Okeene and
north of Watonga. The bridges are numerous and in some
instances are said to be sufficiently large to permit the pass¬
age of a load of hay beneath them. The scenery in this
district is so remarkable that Mr. Chapman states that he is
preparing a bill which he hopes to have passed by Con¬
gress, establishing a "Natural Bridge park" containing
about a hundred i^tural bridges.
While following down the Cimarron valley to the
Great Salt Plain some years ago, the writer discovered
38
COLORADO COLLEGE STUDIES.
an interesting deposit of selenite in the Medicine Lodge
gypsum. It was a mass of several tons' weight forming
the roof of one of the small caves that open upon the river
valley a few miles west of the " plain," where the gypsum-
ledge occupies a position but little above the level of the
"bottom." The mass consisted of an interlocking and partly
interpenetrating group of huge crystals. It was found that
the latter, though readily cut, could only with great diffi¬
culty be removed entire, owing to their toughness and their
interlocking relation. Chisels were driven into the mass
with difficulty. Prying with iron bars was little more
effectual and attended with similar results, the bending of
the crystals causing them to cleave into slabs and sections
or producing an intermolecular fracture that rendered them
opaque. By the destruction of perhaps an equal amount,
some 800 pounds' weight was obtained by two assistants
and myself as the result of several hours of hard work, and
was sent to the museum of Washburn College. The largest
crystal (now split into halves) measures a little over three
feet in length, is two feet wide and a foot thick, and in part
clear enough to read through. It is obliquely penetrated
by a comparatively small crystal at one extremity. It is
the largest crystal of selenite that the writer has ever seen;
but still larger masses are said to have been observed in the
Glass mountains.
Some local use has been made of the Medicine Lodge
gypsum almost since the founding of the towns of Medicine
Lodge and Sun City; but within the last few years two
mills* have been built for th^ manufacture of plaster from it
on a commercial scale, and this is doubtless but. the begin¬
ning of a vast industry that will ultimately be built up in
this great gypsum-belt in southern Kansas, Oklahoma and
*That of Best Brothers at Medicine Lodge, making Keene's
cement as one of its specialties; and the Standard Cement Company,
whose headquarters are at St. Joseph, Mo., and whose mill is on the
north side of the Medicine Lodge river, in the west part of Barber
county, shipping from Croft.
THE PERMIAN SYSTEM IN KANSAS.
39
Texas, a belt which is far greater than the discontinuous
one of the Geuda, and is, indeed, one of the greatest
gypsum deposits in the world.
THE KIGER DIVISION.
The upper division of the Cimarron series is the Kiger
division, so named from Kiger creek in Clark county, Kansas,
a stream that traverses all of the terranes of this division
except the lowest. On the central plains north of the
Ouachita mountains, this division includes all of the rocks of
the so-called "red-beds" that lie above the Medicine Lodge
gypsum. In southern Kansas, it includes the following suc¬
cessive members, beginning with the lowest: the Dog Creek
shales, the Red Bluff sandstones, the Day Creek dolomite,
the Hackberry shales, and the Big Basin sandstone.
The lower part of this division (including the Dog
Creek and Red Bluff terranes as exposed on the Medicine
Lodge river drainage) was reconnoitred by the writer in
1884, '85 and '86, but the first knowledge of it as a whole
was obtained by Prof. Orestes St. John in his reconnaissance
of 1886, and set forth in 1887 in his "Notes on the Geology
of Southwestern Kansas."*
In addition to, other facts given under the heads of
the several formations, relative to the westward extension of
the Kiger, it may here be noted that an outcrop of this div¬
ision, but of undetermined terrane, occurs on the Beaver,
six miles west of Beaver City.
THE DOG CREEK SHALES.
The lowest rhember, or Dog Creek terrane, of the Ki¬
ger consists of some thirty feet, or locally of a less or
greater thickness, of dull-red argillaceous shales, with
laminae of gypsum in the basal part and one or two ledges
of unevenly lithified dolomite in the upper. The color of
♦Fifth Biennial Report of the Kansas State Board of Agriculture,
pp. 132 to 152.
40
COLORADO COLLEGE STUDIES.
these shales resembles that which prevails in most of the
terranes of the Salt Fork division below, more than that of
the Kiger terranes above the Dog Creek. The dolomite
varies from light-gray to dark-gray, and clay-impregnated
portions may partake of the red color of the including
shales. In lithological character, it varies from solid stone
which serves a fair purpose as a building-stone for the
rougher uses, to that which is so contaminated with clay as
to be soft and worthless. It is often cellular or cancellated.
A dark and cellular variety occurs at the top of a remnantal
mound of the Dog Creek at the highest point of the range of
lofty tables that forms the eastern front-line of the Gypsum
hills southwest of Medicine Lodge, this mound being the
most easterly outlier of the Dog Creek formation in Kansas.
The thickness and stratigraphic relations of the Dog
Creek formation are well displayed south of Lake City on
Dog creek, from which the formation is named, and on Lit¬
tle Bear creek, and thence westward in Barber and Coman¬
che counties and the southeastern part of Clark county,
on various branches of the Medicine Lodge river. Salt fork,
and Cimarron river. In Oklahoma, it is seen on the bluffs
of the latter river in the immediate vicinity of the Great
Salt plain.
THE RED BLUFF BEDS.
While the rocks of the Kiger bear certain general
resemblances to those of the Salt Fork division, they yet
present in the main a different aspect. This prevailing
difference is especially due to the thick body of bright- red
rocks that constitutes at once the second member of the
Kiger division and the major part of the Kiger sedimenta¬
tion, viz., the Red Bluff beds.
This formation consists of seme 175 or 200 feet of light-
red sandstones and shales. Its thickness is not fully shown
in the valley of the Medicine Lodge river, having there
been reduced by pre-Cheyenne and later erosion, but is
THE PERMIAN SYSTEM IN KANSAS. 41
exhibited in the valley of the Cimarron river in Clark
county, Kansas, and in the slope north of the Great Salt
plain. Viewed as a whole, it is very irregularly
stratified, the component beds, while consisting of nearly
parallel laminje, being in some cases considerably inclined,
in others curved, and this oblique and irregular bedding,
being on a much larger scale than that of ordinary cross-
bedding, at first glance gives the impression of dips, anti¬
clines and synclines that have been produced by lateral
pressure, the dips being, however, in various directions,
as north, east, etc., etc. It is certain that these older
formations of the Plains must have been subjected to even
more of the dynamic strain due to oscillatory movements
of the earth's crust than the much-fractured Cretaceous
rocks of western Kansas, and it is also probable that minor
inflections and accidents of the strata have been wrought
by the leaching and undermining agencies of solution in
ages past, as they are seen in operation to-day producing
the numerous basins of western Kansas; but it seems to the
writer that neither leaching, which has been suggested by
the late Prof. Hay as the cause of similar irregular bedding
in lower beds at Caldwell,* nor lateral pressure, nor both
of these, should be held wholly responsible for the phe¬
nomena, but that these are partly due to the conditions
under which the sediments were originally laid down.
The Red Bluff beds exhibit the most intense colora¬
tion of any of the rocks of the Cimarron series, being ap¬
proached in this respect only by the Cedar Hills sandstones.
When the outcrops are wet with recent rains, their vivid¬
ness of color is still greater, and the contrasts of their al¬
most Vermillion redness with the other colors of the land¬
scape is most striking. Spots and streaks of bluish or
greenish-gray sometimes occur in the red of these rocks,
but not to nearty the same extent as in the Salt Fork
division.
•Geology of Kansas Salt, p. 5.
42
COLORADO COLLEGE STUDIES.
The sandstones of the Red Bluff are generally too
friable for building-stone ; but in some instances selected
portions have proved bard enough for such use and fairly
durable.
A marked characteristic of most of these sandstones is
their unusually fine texture. When pulverized, or as seen
in soils that have been derived from them, they sometimes
seem like brick-dust. So light are some of their soils that,
walking over them, one may sink shoe-deep, as if walking
on the mellow ground of a well cultivated field.
The sandstones are also porous and, especially where
overlaid not far away by Neocene sands, are often a source
of water. Their springs are rarely strong, being usually
seepage-springs, but their spring-waters are in some in¬
stances nearly as sweet and soft as those coming directly
out of the Neocene sands themselves. Examples of perma¬
nent springs of this sort are seen in Red Bluff sandstone at
the head of a north-side canyon of North Elk creek, on the
Medicine-Elk divide about five miles west of Sun City.
Wells dug in Red Bluff sandstone and which at first are
failures, or yield only a scanty supply of water, sometimes
become valuable wells after the lapse of a few years. The
water of such wells is liable to be more or less saline or
gypsum-tainted, but is frequently fresh enough to be palata¬
ble and available for ordinary uses.
The shales of the Red Bluff are rarely without some
admixture of fine arenaceous matter.
The Red Bluff beds, once uncovered, yield rapidly to
subaerial erosion and their outcrops generally show a
rugged, canyon-cut relief which, in connection with their
bright-red color and their frequent setting-off with dark-
green cedars, makes some of their landscapes exceedingly
picturesque. The sandstones are frequently trimmed off
by stream-erosion in a long, straight, vertical wall that re¬
sembles the face of a quarry. These and less regularly
cut exposures, where rendered conspicuous, have given rise
THE PERMIAN SYSTEM IN KANSAS.
43
to many such local names as "the Red bank," "the Red
bluff," etc. Thus, for example, we have the so-called "Red
bank" on North Elk creek in the northeastern part of
Comanche county, southeast of Stokes hill; and on Bluff
creek, above Protection, is the "Red. bluff "* which gave
name to the former postoffice of Red Bluff, after which in
turn the Red Bluff beds are named.
On the Medicine Lodge river, the Red Bluff beds con¬
stitute the highest surviving formation of the Cimarron
series and occur as far west as Belvidere. At the latter
place, they are unconformably overlaid by the Cheyenne
sandstone, only the lower part, about lOO feet, of their thick¬
ness being represented. On the Salt fork drainage, they
are seen in ravines of the upland slope a few miles south of
Deerhead, underlying sandy soils of probably Loup Fork
Tertiary origin. Thence they extend up the valley of Big
Mule creek to within a few miles of Wilmore, and that of
the Salt fork itself to the vicinity of Avilla. On the Cimar¬
ron river, the location of the eastern border of the Red
Bluff outcrop is unknown to the writer, but it is at least
considerably southeast of the Panhandle line of the A. T.
& S. F. railway, since the formation is beautifully exposed
along that line on the slope south of the river. Westward
on the Cimarron drainage, exposures of this formation ex¬
tend to the lower part of Crooked creek in Meade county,
ascending the creek-valley to Odee. They are also seen
in the lower bluffs of Tainter's creek (also known as Cot¬
tonwood canyon), a beautiful brook heading in the Neocene
sands south of the Cimarron, and entering the river a little
west of the mouth of Crooked creek. The Red Bluff beds
are seen again at intervals on the Beaver in Oklahoma, but
in Beaver county, they are largely mantled with fresh-water
Neocene sediments. They are probably well developed on
»
♦This bluff is illustrated in fig. 18 of Professor Hay's Geological
Reconnaissance in Southwestern Kansas. Bulletin No. 57 of the
United States Geological Survey.
44
COLORADO COLLEGE STUDIES.
the Canadian river and southward, but their extension there
has not been seen by the writer, unless certain limited ex¬
posures seen low down in the valley of that stream beneath
a mantling of Neocene near Canadian, Texas, are part of
them.
THE DAY CREEK DOLOMITE.
Upon the latest of the Red Bluff beds rests a persist¬
ent stratum of dolomite, varying from less than a foot to
five feet or more in thickness. This is the same as the
"gray, cherty, sometimes gypsiferous limestone" noticed
by Professor St. John* as occuring in Clark county at the
head of Day creek. It is a true dolomite, containing with
the carbonate of lime an equal or even greater percentage
of carbonate of magnesia, as indicated by a qualitative an¬
alysis kindly made for the writer by Prof. William Strieby
of Colorado College. Though not of great thickness, it is
an important member of the upper Permian of southern
Kansas and northern Oklahoma owing to its persistence,
which makes it a convenient horizon of reference. It may
therefore be considered a formation by itself and, to dis¬
tinguish it from other and less important dolomites of the
Cimarron series, be called the Day Creek dolomite, after
the above-named locality of its occurrence.
The stone is nearly white in fresh fracture, weathers
gray, and often has a streaked and gnarly grain crudely
resembling that of fossil wood. It is more or less cellular
and, in places, cancellated. Irregular nodules of limonite
are here and there imbedded in it. Its cherty hardness and
fracture are not due to the presence of silica, as one is
tempted to infer, but are characters belonging to it as a
dolomite. It is a durable building-stone, as shown by the
old buildings and corral-walls of the Fares ranch on West
Bear creek, which are built of it; but it is somewhat diffi¬
cult to trim to desired shapes owing to its erratic fracture.
*Notes on the Geology of Southwestern Kansas, i. c., page 141.
THE PERMIAN SYSTEM IN KANSAS.
45
and Mr. Fares informed the writer that when fires were
made in a fire-place that was built of it, the stone began to
"pop" and crack in pieces, showing its unfitness for use
where it would be subjected to much heat. From the skirt
of Mount Prospect and the region of the junction of Hack-
berry and Bluff creeks, the exposures of the Day Creek
dolomite extend almost uninterruptedly westward, past East
and West Bear creeks, including the vicinity of the Fares
place, to Little Sand creek, west of which they are less
continuous. The formation appears, however, in the ravine
that heads just west of Little basin, and it seems probable
that the ledges recorded (I.e., page 142) by Professor St.
John "on Gypsum creek a few miles above Cash City, on
the borders of Clark and Meade counties," as well as a less
characteristic ledge which the writer recently observed on
Crooked creek near the present location of Odee postoffice,
should be referred to the Day Creek formation. A num¬
ber of years ago, the writer observed a stratum of dolomite
capping the so-called Centennial mound* on the old trail
from Kinsley to the Salt plain, in what is now Woodward
county, Oklahoma. Some of the field-notes of that
reconnaissance have been lost; but if it be remembered
correctly, this Centennial mound dolomite was correlated
with that which'is here'called the Day Creek.
At one locality in Clark county, a point on the Little
Sand creek drainage passed by the road from the Fares
ranch to "St. Jacob's well," the Day Creek stratum presents
a peculiar variation. It there becomes a homogeneous, semi-
translucent white rock of remarkably pure aspect, unlike
any other rock with which the writer is acquainted, but
bearing more or less resemblance to fine-grained mar¬
ble, or to onyx or chalcedony. In honor of Mr. Henry
Fares, formerly of the Fares ranch, to whom the writer is
indebted for most enthusiastic and valuable assistance in
*Forinerly called Sentinel mound?
46
COI.ORADO COLLEGE STUDIES.
several of his earlier geological reconnaissances of Clark
county and the formerly so-called Public Lands, it is pro¬
posed to call this interesting lithologic occurrence, or rock-
variety, Faredte.
THE HACKBERRY SHALES.
In Clark county, Kansas, the Day Creek dolomite is
overlaid by 1$ to 20 feet of crumbling, chiefly maroon-col¬
ored shales, including some moderately hard laminae that in
weathering check into small cakes and dice-like chips.
They are well shown in the region of the junction of
Hackberry and Bluff creeks, from the former of which they
derive the name of Hackberry shales. They follow thence
the irregular westerly course of the Day Creek outcrop to
the western part of the county. The most westerly occur¬
rence of the Hackberry formation that has been satisfactor¬
ily identified by the writer is in the southeastern wall of Big
basin; but the writer has observed what he is inclined to con¬
sider as remnants of it on lower Crooked creek, at and above
Odee, while the dolomite of Gj'psum Creek on the Clark-
Meade county border, if referable to the Day Creek terrane,
involves the not unlikely occurrence of the Hackberry
shales with it.
THE BIG BASIN SANDSTONE.
The western, northern and northeastern parts of the
bluffy walls of Big basin are formed largely by the calcar¬
eous sandstonv of the Loup Fork; but on the easterly to
southeasterly quarter the rim of the basin is chiefly of Kiger
sediments, in which the Hackberry shales appear with a
coping of rather massive, blocky, red and grayish-white
sandstone. The latter, from this locality of its typical oc¬
currence, may appropriately be known as the Big Basin
sandstone. It is also seen on Kiger creek, at ihe Fares ranch
on West Bear creek, and elsewhere in Clark county. Its
maximum thickness probabl}' does not anywhere exceed 12
feet. While particolored, it has less of the "poi^^ilitic" char-
THE PERMIAN SYSTEM IN KANSAS.
47
acter than is seen In most of the particolored rocks of the
Cimarron series, the two colors being arranged in two (lo¬
cally three) broad bands, of which one is almost uniformly
red, and one almost uniformly grayish-white with occasional
flecks of red.
At one locality on the eastern rim of the Big basin,
where it is overlaid by, and not abruptl}'^ separated from
an incoherent sandstone of the lower Cretaceous,* the Big
/Basin sandstone is clearly also the highest surviving terrane
of the Cimarron series, and therefore of the Permian, if all
of the Cimarron series be really of Permian age as here
assumed. Moreover, the Big Basin sandstone is the.highest
terrane of the Cimarron series whose occurrence in any
part of Kansas or Oklahoma can here be positively assert¬
ed. Were it also the highest terrane of that series ever
deposited in this region, it would need be accredited as
record of the final shallowing of the great "Dead sea" of
the Plains, marking, as nearly as any terrane could, the
close of the Paleozoic era in this region. But the writer
has an impression (not positive enough to be called a recol¬
lection) that he once observed a narrow remnant of red
Cimairon shale above the Big Basin sandstone at some
point in Clark county; and if this impression be correct, it
confirms what might reasonably be inferred on other
grounds, namely, that terranes higher than the Big Basin
sandstone originally formed a part of the Cimarron series
in this region, and that these, with possibly one or two
minor exceptions, do not outcrop in Kansas, having been
partly removed by erosion in the time-interval indicated by
the great post-Cimarron unconformity and partly preserved
*Tbe soft, gray, ferruginous-stained sandstone that here overlies
the Big Basin sandstone is a remnant of the Belvidere beds. In the
immediate vicinity ^t also underlies a decomposed remnant of the
Kiowa shales, and may be either a western recurrence of the Cheyenne
or a sandstone member of the lower part of the Kiowa itself. Its
relation to a part of the Kiowa shales is fairly well shown in the west
wall of Little Basin, a little way to the eastward.
48
COLORADO COLLEGE STUDIES.
concealed beneath a blanket of Cretaceous and later
deposits.
It might naturally be considered by some that the
transitional character of the horizon of passage from the
Big Basin sandstone to the Cretaceous sandstone rein¬
forced the earlier generally accepted view that the "red-
beds" were Jura-Trias, or at least partly so; but the bond
of continuity which has already been referred to as appar¬
ently existing between the Cimarron series of Kansas and
the paleontologically proven Permian of northern Texas
outweights any argument of that sort, and indicates rather
that the upper and here lighter-colored zone of the Big
Basin sandstone was softened by the invading waters of
the Belviderean sea, and its sediments partially and then
wholly rearranged as the (for this point) initial deposits of
the latter, only gradually becoming supplanted by sedi¬
ments conveyed from other sources.
Supplementary Note.—The Sumner division is named after
Sumner county, which includes nearly the entire breadth of the area
of its outcrop in southern Kansas. The Cimarron series is named
from the Cimarron river, in whose basin the rocks of both of its divi¬
sions are so extensively displayed.
ON THE STRATIGRAPHY OF THE PLATTE
SERIES, OR UPPER CRETACEOUS OF
THE PLAINS.
BY F. W. CRAGIN.
THE PLATTE SERIES.
The rocks of the North American Interior Cretaceous
belong to two great series. The lower of these, consisting
chiefly of limestones, with subordinate terranes of shale,
marl, and sandstone, and having its fullest development in
Texas and Mexico, has been named the Comanche series.
The upper series, into which shales and sandstones more
largely enter, but which has important limestone formations
also, may most appropriately be called the Platte series, after
the Platte river, which, in Colorado and Nebraska, cuts all
of the divisions of the series and all of the formations recog¬
nized as belonging to it in the typical area of its occurrence,
viz., that segment of the North American Interior plateau
which extends from the Rocky Mountains eastward, and
constitutes the higher portion of the Plains.
The Platte series includes the following divisions:
Dakota, Benton, Niobrara, Fort Pierre, Fox Hills, and
Laramie.
Following are brief preliminary notices of some of the
formations that compose that portion of the Platte series
which is included within the limits of Kansas.
THE-RUSSELL FORMATION.
The lower formation of the Benton in Kansas. Named
from Russell, Kansas, around which it outcrops in ravines.
50
COLORADO COLLEGE STUDIES.
Consisting of alternating limestones and shales. The shales
carbonaceous (bluish) to calcareous (light gray). The
limestones including at least two courses that are used as
dimension-stone, the more important of which (commonly,
6 to 12 inches thick) is the Downs limestone (named from
Downs, Kansas, near which are quarries of it,) and which
might also be appropriately called the Fence-post limestone,
as it is extensively used for posts of wire fences. Buildings
and posts from the Downs limestone having a characteristic
and rather neat, striped appearance due to a median yellow,
brown or reddish rusty band in the rock. Outcrops from
valley of Crooked creek in southern Gray county to that of
Republican river in western part of Republic county,
thence crossing Republican-Little Blue divide and passing
into Nebraska. Formation includes the Globigerina bul-
loides "Lincoln marble." Characteristic fossils: Trinacrom-
erum bentonianum, Inoceramus labiatus, I. fragilis (small
phase), Prionocyclws ivoolgari (small phase), etc.
THE VICTORIA FORMATION,
Or Victoria clays. The upper formation of the Ben¬
ton in Kansas. Named from Victoria, Kansas, which is on
the outcrop, the clays being also cut largely by Victoria
creek. Highly carbonaceous, almost black, sticky clay-shale,
with a zone of frequently large "cannon-ball" septaria in the
lower part, the Cannon-ball zone, supposed to be the same as
that of Cannon-ball crossing on the Missouri river, illus¬
trated in Hayden's reports.
Outcrops extend from Walnut creek, Ness county,
Kansas, (fromnorth branch of Pawnee river in Hodgeman?)
to Whiterock creek and Republican river in northwestern
Republic county, and thence through Nebraska, etc.
Fossils: immense Prionocyclus woolgari, Scaphites warreni,
Scaphites vermijormis, Inoceramus labiatus, Plesiochelys lovii, etc.
THE PERMIAN SYSTEM IN KANSAS. 51
THE OSBORNE LIMESTONE.
Named from occurence at Osborne and in Osborne
county, Kansas. Crowning the Victoria shale and consituting
the lower formation of the Niobrara. Limestone in rather
thick courses. "Devil's Gap," in southeastern Rooks
county, is in this limestone. Courses thicker than in Rus¬
sell formation; some thin ones, especially at summit. Lime¬
stone harder and better for building than Smoky Hill
chalk, but softer than and inferior to the Downs limestone.
Formation forms bluffs in forks of Walnut creek in
Ness county; of Solomon river in Osborne county; occurs
at Ft. Hays, forming upper member of the "Ft. Hays"
(lower Niobrara and Benton) of Prof. B. F. Mudge; and
forms bluffs on Whiterock creek, from above Lovewell to
near Whiterock, passing thence into Nebraska through
Whiterock-Republic divide. Fossils: Inoceramus deformis,
I. brownii, Radiolites austinensis, etc.
THE SMOKY HILL CHALK.
Upper formation of the Niobrara. Named from the
Smoky Hill river, on which it is magnificently developed.
Chalky and marly limestones and chalk. Bluish and marly
in the lower or Trego zone, (named from its conspicuousness
in Trego county, Kansas,) and yellow (to white, red, etc.)
and more chalky in the Norton zone (named from occur¬
rence at Norton and in Norton county, Kansas). A horizon
of jasper, the Graham jasper (named from its occurrence
in Graham county, Kansas) near the upper limit. Lenses
of hard, so-called "Bell-rock" in base or transition to
Osborne limestone. On Smoky Hill river from western
Ellis county to vicinity of Ft. Wallace; thence chiefly
northward and northeastward. Includes "Castle Rock"
in Gove county, and many similar monumental forms.
Fossils: Inoceram%s {Haploscapha) grandis, Uintacrinus
socialis, the huge fish, Portheus molossus, many large reptiles,
Cimoliosaurus snovii and other enaliosaurs, with mosasaurs.
52
COLORADO COLLEGE STUDIES.
pterosaurs, turtles, etc.; toothed birds, etc.: a rich and
unique fauna of unusual importance and interest, described
by Cope, Marsh, Williston, etc.
THE LISBON SHALES.
Named from Lisbon, Kansas, near which they outcrop.
Dark-bluish and brownish shales. Seen above the Smoky
Hill chalk in Logan and Wallace counties, Kansas, and
Elbert county, Colorado. Contain concretions of yellow
phosphate of iron. (Fide Prof. G. H. Failyer.) Sup¬
posed to be lower Ft. Pierre. Fossils: Inoceramus barabini,
Baculites, limpets, etc.
THE ARICKAREE SHALES.
Named from Arickaree river, on which they occur in
Cheyenne county, Kansas, and an adjoining part of Colo¬
rado. Light-colored, olive, yellowish and brownish-gray
shales. Referred to the lower part of the Fox Hills divis¬
ion. Fossils: Pteria fibrosa, Scaphites nicollettti, etc.
PRELIMINARY NOTICE OF
THREE LATE NEOCENE TERRANES
OF KANSAS.
BY F. W. CRAG IN.
At several localities in Kansas, typically on Bluff creek,
in Clark county, in the immediate vicinity of the old Van-
hem postofiice, occurs a succession of three terranes:
(i) the lowest, consisting of gravels and sands laid
down in deep and broad valleys; (2) the middle, consisting
of a wide-spread horizon of white to brownish (rarely
greenish) volcanic ash; and (3) the highest, consisting of
yellowish-brown lacustrine or slack-water marls, contain¬
ing variously shaped concretions of carbonate and silicate
of lime (the former called "native plaster").
THE MEADE GRAVELS.
For the ancient (supposed late Pliocene) gravels, the
name Meade gravels is proposed, after Meade Center,
where they constitute the artesian-water-holding formation.
They contain abundant remains of horses, llamas, elephants,
turtles, etc., and rarer remains of Megalonyx and Felidse, the
species of which will be listed elsewhere, but which include
Elephas imperator (f), Megalonyx leidyi, Equus complicatus.
Equus curvidens, Auchenia huerfanensis, etc., indicating the
fauna of the Equus beds. These gravels are mostly un¬
consolidated, but frequently contain hard ledges in Meade
county and elsewhere. They are generally 10 to 30 or 40
feet in thickness and frequently grade into the Pearlette.
54
COLORADO COLLEGE STUDIES.
THE PEARLETTE ASH.
The volcanic ash may be called the Pearlette ash, from
the old postoffice of Pearlette, in Meade county, where the
writer studied an ash-bed of this terrane in 1884. The
Pearlette rarely contains fossils. These do not differ from
those of the underlying Meade formation. The ash attains
a thickness of 13 feet in a bed southwest of Meade Center,
considerably less in Clark and the many other counties of
Kansas (especially western Kansas), Nebraska, etc., in
which the ash has been found. It occurs west at least to
Huerfano Park, Colorado (Hills), and east to Sioux City,
Nebraska (Todd), and Galena, Kansas (Williston). Ii
frequently passes into the Kingsdown by imperceptible
gradations.
THE KINGSDOWN MARLS.
For the marls, the name Kingsdown marls is proposed,
after the station of that name west of Bucklin on the Rock
Island railway, between which and the upper part of Bluff
creek, Clark county, they are finely exposed in deep ra¬
vines. They are very rarely fossilferous. Elephas was found
by the writer in them nearVanhem. They are typically de¬
veloped in Meade county also. They are apparently not
less than 100 feet in thickness in Clark county, and more
than twice that thickness at certain localities on the divides
further westward.
All three of the terranes here described are supposed
to be formations of the Tule division of Cummins (Equus
beds of Cope), and to represent late Pliocene time. They
are conformable with each other, and unconformably over¬
laid with local beds of marl, sand, diatomaceous earth, etc.,
of supposed Quaternary age.
Colorado College®
Studies.
VOLUME VII.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
tOLORADO SPRINGS, COLO.
November, 1898.
CONTENTS.
- ' f' I
Page.
(1) Literature for Children, 1-15
Prof. E. S. Parsons.
(2) AVarniing Up, 16-29
Dr. E. G. Lancaster.
(5) E]quations of Motion of a Viscous Liquid—
Part I, 30-48
Mr. p. E. Doudna.
THE OUT WEST PRIHTINQ AND STATIONERY CO.,
COLORADO SPRINOS.
LITERATURE FOR CHILDREN *
Prop. E. S. Parsons.
What children are meant by our subject? Though the
honor of speaking in this presence has been given me by you
who are kindergarten teachers, I have not interpreted your
request as limiting me to the discussion of literature suited
to children of the kindergarten age. If I had so interpreted
it, I should have been compelled at once to decline the invita¬
tion, for I feel myself wholly unqualified to speak upon a sub¬
ject requiring technical knowledge and experience of a sort
which I do not possess. I shall try to unfold the thought of
literature for children of all ages, those who are just able to
understand what is read to them, and every grade up to that
which has just crossed the invisible line beyond which is youth.
Five and sixteen are good theoretical limits.
What is literature? A second question more important
than the first. We ought to resent the loose use of the term,
for it has a definite meaning, and one which ought to be kept
sacred. All writing is not literature. Intellect cannot make
literature; so writing that seeks simply to inform, to instruct,
is not literature. Into writing which can be called by this
high name, intellect will enter, but it must be intellect, aerated
by imagination, to use Lowell's favorite phrase. The wind of
the spirit must blow through the essay or the poem if it is to
win the right to be called literature. And this quality of im¬
agination must have given to the writing an emotional and an
artistic value, the two being closely linked together, before it
can take its place in the list of the immortals. Imagination
and feeling, then, are the final tests of litei-ature: imagination,
which apprehends the deeper significance of life and embodies
it in forms of beauty, and feeling, which is the response of the
soul to the vision.
*An address delivered before the tweaty-second anaual sessioD of the Colorado
Teachers' Association.
2
CoLOBADO College Studies.
Judged by these high standards, there is not much which
can be called literature. Our question to-day is, to what part
of this body of writing shall children be introduced? This
involves the larger question, are children capable of appreciat¬
ing literature at all? Shall we give literature to children?
Children will read—that is, most children will. This fact
may be taken for granted. The child who will not read under
right conditions is an anomaly. The mind in childhood is as
hungry as the body, and those of us who are parents know
that our boys, as some one has put it, are hollow to their boots.
The mental digestion of the child is as strong as his appetite,
and he reads and digests with marvelous rapidity. Harriet
Martineau once told a story that well illustrates the point. " I'
have seen a schoolboy of ten," she says, "lay himself down,
back uppermost, with a quarto edition of 'Thalaba' beforehim,
on the first day of the Easter holidays, and turn over the leaves,
notwithstanding his inconvenient position, as fast as if he was
looking for something, till in a few hours it was done, and he
was off with it to the public library, bringing back ' The Curse
of Kehama.' Thus he went on with all of Southey's poems
and some others through his short holidays, scarcely moving
through all those days except to run to the library." And
Miss Martineau adds: " He came out of the process so changed
that none of his family could help being struck by it. The
expression of his eye, the cast of his countenance, his use of
words, and his very gait were changed. In ten days he had
advanced ten years in intelligence; and I have always thought
that this was the turning point of his life. His parents wisely
and kindly let him alone, aware that school would presently
put an end to all excess in this new indulgence."
Children will read, and read voraciously. Publishers are
more and more recognizing this fact. The law of demand and
supply is finding new proof in the rapid accumulation of juve¬
nile literature. Every publisher's list contains large numbers
of new books for the young. Library tables swarm with maga¬
zines and weekly papers—good, bad and indifferent—designed
to supply this voracious appetite. Children will read, and the
publishers are giving them reading.
Litebature fob Children.
3
But is this printed matter, which is every year pouring out
in a stream of huge volume from the presses of the world,
what we want our children to read? Is it enough to turn
them loose in a library of such books and papers? If so, then
there is no need of my saying anything more. Nothing more
can be said except to suggest a classification of the books by
which children may be taught to gobble them down system¬
atically, and so more exhaustively—taught to scrape the plat¬
ter clean, as it were, at the literary banquet. Children have
strong digestions, but such a process, I fear, would justify the
words of the " Fable for Critics:"
" Reading new books is like eating new bread,
One can bear it at first, but by gradual steps he
Is brought to death's door of a mental dyspepsy."
Is such a process safe for our children? Is it desirable?
There are great authorities who have given no uncertain
answer to these questions. Charlotte Yonge has said: "We
have little liking for books for boys," and she goes on to say
in conclusion of a somewhat extended treatment of the sub¬
ject: " Our conclusion as to children's literature is a some¬
what Irish one, for it is, use it as little as possible, and then
only what is substantially clean and good. Bring children as
soon as possible to stretch up to books above them, pi-ovided
those books are noble and good." Charles Dudley Warner
speaks with still greater emphasis: "As a general thing, I do
not believe in books written for children. * * * * j am
not sure but it would be a gain if all so-called children's books
were destroyed and the children depended altogether on what
we call adult literature. I know of a family of young children
who read, or had read to them, a translation of the ' Iliad.'
They were perfectly captivated by it, and they got more out
of it, even though not able to read it themselves, than they
would have got from a whole library of the stuff children now
commonly read."
You remember Emerson's dictum, the first of his three
rules of reading; "Never read any book that is not a year
old," implying that if you wait a year before reading a
book, in a vast majority of cases you will not read it at all.
4
Colorado College Studies.
Nowhere does this rule apply so well as in the case of
children's books. If we do not accept in its entirety the
position which the first two writers quoted above have taken,
we can at least accept it with Emerson's qualification. If at
the end of a year the book has proved it has a right to live,
then let the child read it. Only most of us, after having
thoroughly studied the subject, would desire a still longer
period of probation.
If the child should not read so-called children's books, what
should he read? Miss Yonge and Charles Dudley Warner
have already answered the question. Let them read adult
literature—the books their elders read. This statement needs
at least one limitation. Let the children read, not what their
elders read, but what their elders ought to read, for the grown¬
up members of the family, as often as the children, read the
latest and the trashiest books. In fact, what the children
read is largely determined by what their elders read. Trash
on the library table means trash in the nursery.
But the question rises at once in many of your minds, is
the child capable of understanding adult literature? Is there
not the danger of shooting above the heads of the children in
seeking to limit them to such books?
It would not do before such an assemblage as this to base
our answer to such a question on anything less than child
study. This is now the fashionable subject of research, and
one of our good fashions it is, too, though it has its absurdi¬
ties, like most other fashions. What are the characteristics
of the child mind which has this voracious literary appetite?
Theories have no weight in this age unless they are theories
that have developed out of facts. " Children are indeed treated
and written about sometimes," said a very wise writer on our
general theme more than thirty years ago, " Children are
indeed treated and written about as though they were little
fools, and any baby talk or twaddle were good enough for
them; but we are in the main inclined to believe that they
are great fools who make this mistake, and so sadly libel
God's handiwork." " The great human mind is in the little
child as in the gray-headed sage," but the intellect—what we
Liteeatuee foe Childeen.
5
mean in our formal use of the word—is not the faculty most
early developed. We who are parents often find our children
startlingly good reasoners, but that is not the aspect of the
mind which stands out in them most prominently. Any one
who knows children knows that the affections and the imagina¬
tion are what chiefly characterize the child nature. " Give a
child a little love and you will get a great deal in return,"
some one has said. Give a child a glimpse into the imagina¬
tive world, and he will build castles and people them, fight
battles and win them, create a new world and live in it, far
from the madding crowd of life's cares and pain.
" The supreme endowment of human nature is the gift of
imagination," and it is given to the child at the beginning of
life. Oftentimes the imagination atrophies for want of use.
But it need not have this fate. The poet, the seer, is he who
does not let it die, but who, through ' all his life, looks out
upon nature and men with the eyes of a child, seeing not
merely what is at the surface, but what is underneath, not
merely the hard, apparent reality, but the blessed and more
real ideality.
Many persons, hard and fast realists, grow angry at the
suggestion that there is any value in the fancies of childhood
and in the power which calls them into being. They would,
if they dared, criticise the Creator for mingling this ingre¬
dient in the human composition, and they seek to eliminate
it by denying the child mind its natural food of fairy story
and myth, by strapping it about with the intellectual bands
of the alphabet and the spelling book and the prosaic primer
and arithmetic, much as the Chinese mother of high caste
binds and dwarfs the foot of her little baby girl. To the an-
nointed eye'such realists have the grotesque — the pitiful —
hobble of the fine Chinese lady of mature years. But the
satisfaction of the imagination and the afPectionsin early life
does not mean the crippling and dwarfing of the intellectual
powers. They will unfold soon enough. They are simply
latent. And Vhen they begin to develop, and after they have
grown to maturity, nothing will aid them so much in doing
their work as " the witch, imagination."
6
Colorado College Studies.
The affections and the imagination, then, are the powers
which dominate the child nature. Let us revert to what we
said about literature: "Imagination and feeling are the final
tests of literature." Imagination and emotion, the chief traits
of childhood; imagination and emotion, the chief tests of
literature—the two were evidently made for one another.
It is singularly interesting that three of the greatest
classics of childhood were not written for children at all.
"Pilgrim's Progress" was a new type of sermon written by
the tinker preacher in his prison cell at Bedford; " Robinson
Crusoe " was a pseudo-history from the pen of one of the first
great English realists; " Gulliver's Travels " was a political
satire by the greatest of English satirists. The same thing
is true of the stories of the Bible, of the " Arabian Nights,"
of the folk lore which strikes a sympathetic chord at once in
the child's nature. The truth is that the childlike is the
eternal. Goethe said at the close of his " Faust" that the
Eternal Womanly is to lead us on. Has not our age, by rea¬
son of its more intimate knowledge of human life, come to
the profounder truth that it is the Eternal Childlike which is
to lead the world to its final perfection? At this season the
Christ from His manger cradle sways the world, and the
heart of child is always the best standard of religion, charac¬
ter, art, literature. Except ye be converted and become as
little children ye cannot enter the kingdom of painting or of
books any more than the kingdom of God and His Christ.
Child study, then, reveals the fact that the child nature is
the counterpart of what is best in books, that children can
appreciate literature. But do the conclusions of the psycho¬
logical laboratory find themselves sustained in the practical
experience of those who have had to deal with children? You
remember that beautiful story from the pen of Laura E.
Richards, " Captain January " — one of those books of recent
times which at once reveal the fact that they are literature.
The red dory was just about to set out for the lighthouse
home when the captain was hailed by an old friend with the
same title. The conversation drifted straight to the topic
always uppermost in the lighthouse keeper's mind, his " little
Literature for Children.
7
gal." "'She's learnin!' he added proudly; ' learnin' well!
I'll bet there ain't no gal in your school knows more nor that
little un does. Won'erful, the way she walks ahead.'
' Get the school readers, hey, and teach her yourself, do
you?' queried Captain Nazro.
'No, sir!' replied the old man; 'I don't have no school
readers. The child learns out o' the two best books in the
world—the Bible and William Shakespeare's book; them's all
the books she ever seed—saio, I should say.'
'William Shak—' began Captain Nazro, and then he broke
off in sheer amazement, and said simply,' Well, I'm blowed!'"
Then follows the charming story of the little ten-year-old
child with " her cloud of pale-gold hair " and her soft, deep,
shadowy blue eyes, to whom Samson and Imogen and Ariel
were as real as the cold waves that washed her to the rocky
shore and to the warmth of the old sailor's heart. " An ideal
picture," you tell me. Is it merely ideal, or was it drawn from
life? Last May I received a letter from an Omaha lady in
which, writing about another subject, she spoke of her little
girl, then nine years old: " M is very fond of her father's
library. * * # * The books she is simply devoted to
are the plays of Shakespeare and the Bible." Was Captain
January so far wrong in taking the advice of his minister and
bringing up the " little gal" on those, the two best books in
the world? Harriet Martineau, after relating the story I have
quoted, tells of her own childhood-reading: "I devoured all
of Shakespeare, sitting on a footstool and reading by firelight.
* * * * I made shirts with due diligence, being fond
of sewing; but it was with Goldsmith, or Thomson, or Milton,
open in my lap, under my work, or hidden by the table." One
of our own State teachers, one whom we all delight to honor,
told me a few weeks ago that he had read all of Goethe's
"Faust" with his little thirteen-year-old girl, to her great
enjoyment, and that last summer she read alone all of Chaucer's
" Canterbury T^es." Many teachers have found young chil¬
dren delighted with Dante. I have to my own satisfaction
discovered that little children, not yet able to read, will be
deeply interested in the stories of the Bible read to them from
8
Colorado College Studies.
the Book itself, where they turn to their plays from the read¬
ing of a paraphrase of the stories written expressly for chil¬
dren. The truth is, as Miss Burt has stated it in her book,
which contains so many wise words: "Age has little to do
with the ability of children to receive classic thought." Illus¬
trations of this fact could be given by almost any teacher who
has enough of the literary spirit in himself to be competent
to teach literature.
It has been wisely said that a taste of a great thought is
worth far more than the full comprehension of a small one.
No teacher ought to expect, or to desire, the full comprehen¬
sion on the part of a child of a great work of the imagination.
Nothing is so inimical to the development of a genuine literary
appreciation as the insincerity which a teacher will invariably
foster by such expectations. But in literature it is not true
that a bird in the hand is worth two in the bush. A little
glimpse into a large and generous world is far better than the
full understanding of a mean and paltry one. The child needs
something that will expand his nature, something he can grow
to, not leave behind. One would hardly think of citing Dr.
Johnson as an authority on the education of children, espec¬
ially when it is remembered that it was he who had the most
to do with making our English orthography such a terror to
young and old alike, but no one ever said a truer word on the
subject than this: " Babies do not want to hear about babies;
they like to be told about giants and castles, and of somewhat
which can stretch and stimulate their little minds."
Of course, what has just been said does not mean that all
pieces of great literature are equally fitted to a child's mind
at any period in its life. But it does mean that it is not nec¬
essary to go outside the world's great literature for fit mental
food for a child's imaginative and emotional nature.
The problem, then, as Mr. Horace E. Scudder has put it,
is not one of creation, but one of selection. " The task is to
find literature for the child, not to make it. The permanent
in literature springs from the necessity of the writer to create,
not from the attempt to fit the creation to the needs of the
reader."
Liteeature for Children.
9
Literature is a spontaneous product; it cannot be made to
order; it makes itself. He who attempts to make it to order
fails before he begins. Genius is unconscious, and builds
better than it knows; it jjroduces because it must; and its
readers, usually a later generation, recognize the full meaning
of what has been written. The work of him who is to guide
a child's reading is to select out of the works which bear the
unmistakable stamp of genius—a stamp which the test of time
always reveals—those which are best suited to the child at
the particular stage of his development.
But can anything more definite be said? I have no desire
to give lists of books suited to children. Such manuals as
Miss Burt's "Literary Landmarks" and Hewin's "Books for
the Young" will supply such lists for those who need them.
But a word or two of more detailed suggestion will not be
amiss. Poetry will find its place early in a child's reading,
if not at the beginning. It is concentrated emotion and im¬
agination, and much of it is as simple literature as there is in
the language. Mi\ Scudder is of the opinion that the poetry
which children should first read by themselves should be, not
Whittier, nor Longfellow, nor Wordsworth, but "Mother
Goose." His reasons are well worth repeating: "'Mother
Goose' helps the child to make a passage from the known to
the unknown. The cat he knows, the boy he knows; but the
cat in the well, little Johnny Green, big Johnny Stout, the
bell with its swinging, resounding note — all these are in the
region of the just not known; and when he reads, half sings,
the ditty, his mind is given wings with which to soar a little
way. Again, ' Mother Goose' is cheerful, and the task of
reading literature is lightened. Further, ' Mother Goose' is
full of human associations, and entering literature by these
passages, the child is treading steps worn by generations of
use. There is no waste. He is becoming familiar with the
permanent in literature; he is not conning that which will be
left behind witti childhood. Rather, he is acquiring a cur¬
rency which will, in later days, be drawn forth for use in
the exchange when ' we that are children have children.' "
10
Colorado College Studies.
After " Mother Goose " Mr. Scudder suggests simple poems
of Whittier, Longfellow, Blake, Wordsworth. In prose every
teacher, as well as every parent, knows there is no book for
young, as well as old, students of literature like the Bible.
In the Bible we have imagination and emotion; we have sim¬
plicity combined with exquisite purity of thought and style;
we are dealing with what has endured the test of time; we
are introducing the child to what is of permanent value, to
that which alone can unlock much of what is best in English
literature. Macaulay's remark that he who aspires to be a
critic of English literature must have the Bible at his finger's
ends has received another iteration in a recently published
utterance of the professor of the English language and litera¬
ture in Tale University (in a paper upon Nineteenth Century
literature) that "it would be worth while to read the Bible
carefully and repeatedly if only as a key to modern culture,
for to those who are unfamiliar with its teachings and diction
much that is best in the English literature of the present
century is as a sealed book."
Mrs. Wesley, it will be remembered, the day her children
were five years old, set them to learning the alphabet. The
second day she put them to reading in the first chapter of
Genesis, and made the Bible thereafter their text-book. Such
training produced not merely the superb energy of John
Wesley, but also the rare poetic power of his equally gifted
brother, Charles.
It is almost a truism to quote John Buskin's experience,
but to omit his testimony is to fail to call to the stand the best
witness of the influence of the Bible as literature. He tells
the story in the early part of "Prseterita": "I have next with
deeper gratitude to chronicle what I owed to my mother for
the resolutely consistent lessons which so exercised me in the
Scriptures as to make every word of them familiar to my ear
in habitual music,—yet in that familiarity reverenced, as trans¬
cending all thought, and ordaining all conduct. This she
effected, not by her own sayings or personal authority, but
simply by compelling me to read the book thoroughly, for
myself. As soon as I was able to read with fluency, she be¬
gan a course of Bible work with me, which never ceased till
Literature for Children.
11
I went to Oxford. She read alternate verses with me, watch¬
ing, at first, every intonation of my voice, and correcting the
false ones, till she made me understand the verse, if within my
reach, rightly and energetically. It might be beyond me alto¬
gether—that she did not care about—but she made sure that as
soon as I got hold of it at all, I should get hold of it by the right
end. In this way she began with the first verse of Genesis,
and went straight through to the last verse of the Apocalypse—
hard names, numbers, Levitical law, and all—and began at
Genesis the next day. * * * * After our chapters (from
two to three a day, according to their length, the first thing
after breakfast, and no interruption # * * * allowed)
I had to learn a few verses by heart, or repeat, to make sure I
had not lost, something of what was already known; and with
the chapters thus gradually possessed from the first word to
the last, I had to learn the whole body of the fine old Scottish
paraphrases, which are good, melodious and forceful verse,
and to which, together with the Bible itself, I owe the first
cultivation of my ear in sound." And concluding his dis¬
cussion of the whole matter, he says: " Thongh I have picked
up the elements of a little further knowledge—in mathemat¬
ics, meteorology and the like, in after life — and owe not a
little to the teaching of many people, this maternal installa¬
tion of my mind in that property of chapters I count very
confidently the most precious, and, on the whole, the one
essential part of all my education." It was this which gave
him the place accorded him without any reservation by
the latest authoritative historian of nineteenth century liter¬
ature, that of the greatest of English prose writers.
Such readings in the Bible, and in simple poetry, with a
large intermingling of fairy stories and folk lore, will make
up the bulk of a child's early reading. What shall follow?
Some say, after such a beginning turn a child loose in a well
selected library and let him browse. Such an experience is
of the utmost value to the child. It leads him into familiarity
with books. 5e tastes many, and is led into fascinating re¬
gions before unknown. The delight of the explorer is added
to the delight of the reader. Lowell began in such away the
extensive browsings which made him what he called himself.
12
Colorado College Studies.
the last of the great readers. Led by his own inclination,
John Fiske had read at seven Rollin, Josephus, Goldsmith's
"Greece," Shakespeare, Bunyan and Milton. As some one
said of this reading of his, " I dare say he skipped to get the
stories, but they were great stories." At eleven he had read
Gibbon, Robertson, Prescott, Froissart. This was his reading
for pleasure, and was wholly apart from the intense study
going on at the same time.
But objections have been and can be brought against this
habit of reading. One, which is directed not merely against
this, but against much of what has already been said, is that
it means the overcrowding of the child's brain. In an article
published during the summer in one of our best weeklies, a
writer discussed this objection under the question, "Are Our
Children Precocious or Infantile?" and she concluded that,
while naturally quick, our American children are in reality
infantile in their acquirements. Part of the fault must be
laid at the door of the necessity we are under of educating
children in regiments, but part also must be answered for by
the foolish notion that it is a severer tax on the brain " to
learn that a certain combination of three letters means cat
than that a certain furry creature, having a long tail and
catching mice, is a cat," that it breaks down the brain power
to read Southey's "Life of Nelson," but builds it up to read
Oliver Optic's "Soldier Boy" and "Sailor Boy." The opposite
is the truth. The book full of unreality and sentimentality
without genuine emotion and high imagination is what breaks
down the mind, and with it the body, while the good book
is a tonic, " as refreshing and strengthening as the sunshine
and the sea water."
But a more definite objection is urged to this habit of
library browsing. It is said that if the library is at all inclu¬
sive of great literature there will be much in it which will pol¬
lute the child's imagination. But is this true? Has any one a
grain of evidence to support the theory that a child, early
taught to love the best literature and drawn to it of its own
accord, will be polluted by the coarseness which is here and
there a blot upon it? The little girl who last year read through
the "Canterbury Tales" expressed to her father her delight,
Literature for Children.
13
but said there were some things in them which Chaucer ought
to have been ashamed to write. Did it hurt the child to read
those things and let her purity condemn them? Harriet
Martineau, to whose wisdom I have already appealed, says:
" The last thing that parents need fear is that the young reader
will be hurt by passages in really good authors, which might
raise a blush a few years later. Whatever children do not
understand slips through the mind and leaves no trace; and
whatever they do understand of matters of passion is to them
divested of mischief. Purified editions of noble books are
monuments of wasted labor; for it ought to be with adults
as it is with childreu—their purity should be an all-sufficient
purifier."
But, believing as I do that, where it is possible, this brows¬
ing habit should form a part of every child's education, it is
not everywhere, or in every case, possible. It is a rare excep¬
tion to find a home with such a well-selected library. Most
homes have nothing worth the name. The public library in
most places does not permit free entrance to the shelves. The
book stall, which meant so much to a browser like Dr. Johnson,
has not become much domesticated in America. The child
cannot be taught to browse, because there is no pasturage.
And more than this, such reading, while valuable as an
adjunct, is too desultory to give a full and rounded introduc¬
tion to literature. It is the opinion of those who have most
carefully studied this subject that " between the ages of six
and sixteen a large part of the best literature of the world
may be read if taken up systematically at school," and the
writer who makes this statement adds, " that the man or woman
who fails to become acquainted with great literature in some
form in that time is little likely to have a taste formed later."
Such a wide acquaintance with literature cannot be obtained
by bi'owsing; browsing must be accompanied by systematic,
developing courses of reading.
At the risk of wearing out your patience, I must say a few
words about still another subject. What end shall we set be¬
fore the child to be gained by i-eading? No end at all, we can
say at once. Reading to the child ought to be an end in itself.
" We get no good by being ungenerous even unto books,
And calculating profits, so mucli good by so much reading."
14
CoLOEADO College Studies.
But what end shall we set before ourselves that the child
shall gain from the reading? " Many teachers have felt," as
Mr. Scudder has so pithily put it, " that Pegasus ought to be
hitched to a tip cart," that reading should teach history, geog¬
raphy, biography, science — in other words, that literature
should be made to help the child to obtain information, a
purely intellectual achievement. But the writer of literature
did not write to give information. He wrote because he had
to, because it was the great joy of his life to make the product
of his imagination live in the written word. And the spirit
in which he wrote the book is the spirit in which it should
be read. To teach geography by it is to make it tasteless and
insipid; to make it a medium of criticism is to make it dead
and joyless. The child should learn to delight in it, to read
it only for the delight it can inspire. If the child does not
like what is given him to read, let his choice prevail, and
let the teacher, or parent, study to find what will delight him.
Those who persist in trying to harness up Pegasus to practi¬
cal things may find it necessary to insert in the newspaper
the kind of advertisement which Lowell suggests John Bull
will some day have to put into the London Times:
" Lost, strayed or stolen, from the farmyard of the subscriber, the
valuable horse Pegasus. Probably has on him part of a new plough
harness, as that is also missing. A suitable reward, etc.
"J. Bull."
What has been said at once answers the objection that the
use of great literature in the schoolroom will kill it for the
scholars for all the future. Certainly it will be so killed if
the teacher does not know what literature is, and treats it as
he would a dry-as-dust text-book. But the teacher who, in¬
stead, leaves criticism alone, explains only enough to stimu¬
late the child's interest, and seeks to lead him out into the
perennial delights of the great creations—he will never
have to bear the accusation of killing a good book. " The
great end of literature is not to inform, but to inspire." Let
us thoroughly grasp this truth and we shall never again teach
literature as it has so often been taught.
To accomplish what has been set forth will require a wise
planning of a child's time. We must remember that a child's
Literature for Children.
15
early years are in many respects the most precious of its life.
A wise mother told me a few days ago that, hard as it seemed
to some of her friends, she had never allowed that most ex¬
cellent boy's and girl's paper, the Youth's Companion, to
enter the house. Not that she objected to a single word
printed in it, but she felt that it had a too dissipating influ¬
ence upon her children's reading. Coming week after week,
it gave her children no time for the reading of great books—
books which have stood the test of time, and have been a
fountain of literary inspiration. The wisdom of her choice
for her children is illustrated by the fact that a few weeks
ago her first born was elected to write the ode for the gradu¬
ating exercises of his class at Harvard next June. It would
be well for us all to ask ourselves the question, does it pay
for us, or for our children, to give to the reading of current
books so much of the time we might give to what has proved
itself to be the world's greatest literature?
The results upon the child of such reading as I have been
advocating are too evident to detain us. A child, after his
earliest years, talks like those with whom he associates. "Live
with wolves and you will learn to howl," runs the proverb.
Live with the great masters of the English speech, and if there
is any literary instinct in you, you will learn to use clearly,
simply and musically the greatest of all languages. But this
is by no means the most important result to be gained. This
is an age full of unconscious, if not conscious, materialism.
Aspiration fades more quickly to-day than ever before from
the human soul. Imagination and the higher powers of the
soul tend to die in the suffocating atmosphere of mere fact.
But in him who has been taught in youth to wander in the
green pastures and beside the still waters of our great Eng¬
lish literature the soul will not die. For him there will
always be open what the poet Spenser so beautifully called
"the world's sweet inn," where he can ever find rest and re¬
freshment, and in which there is always to be found a large
upper chamber called Peace, whose windows open toward the
sun's rising.
WARMING UP.
DB. E. G. LANCASTER.
It is a common and generally observed phenomenon that
when one starts for a long walk there comes a period of
fatigue, which, with many people, passes away after continued
walking. The same phenomenon may be noticed with most
people in any kind of mental or physical activity. A student
sits down for a long period of study or writing. There may
be at first a feeling of fatigue or awkwardness of that he has
not yet " found the combination " which, after a time, gives
place to a growing facility that increases until exhaustion
demands a rest.
The same thing may be noticed in animals. Dogs on the
chase, the animals pursued, and especially race-horses show
the etfect of warming up. It is said of two famous trotters,
each of which has reduced the world's record within a few
years, that the period of warming up was very character¬
istic. One was driven two miles at a 2:30 gait, rested, rub¬
bed, taken out for his fast mile but driven a full mile at about
the same pace as before, until approaching the wire, when he
was driven at full speed and the record was taken thus on the
fourth mile. So much warming up was necessary. The
other was jogged one mile, rubbed, then taken to the quarter
pole and gradually urged to her highest speed and the record
was taken on this the second mile.
Athletes, especially ball-players, realize the importance of
practice just before the games, to be followed by a slight rest.
A pitcher would hardly enter the box till he had got his arm
in working order by a few minutes' practice. Orators often
are dull at first but warm up. It is said that Wendell Phillips
was often hissed for his slow, uninteresting speech but rallied
to the occasion at such times with his masterly oratory. We
need not multiply instances. It can be seen and felt almost
anywhere or any time, in one way or another,
Warming Up.
17
It fell to my lot in the psychological laboratory, at
Clark University, to determine if possible exactly what hap¬
pens in this warming up process and whether the cause is
located in the brain, muscle, or elsewhere. The results ob¬
tained were certainly suggestive. Having in mind the work
done by Mosso, and especially the closely related work of
Lombard, we began in a similar way with the ergograph,
which is a machine for measuring work done by registering
the height to which the weight is lifted each time. We used
the middle finger of the right hand. The muscles are so
closely related in the forearm, and in some persons probably
grown together to such an extent that the experiment there
was valueless. When one combination of muscle fibers fa¬
tigued, another took its place and the finger could be worked
with considerable power, though variable, all the time. We
then arranged a thimble for the index finger and a hand rest,
to which the hand was bound so that it could not be tilted to
allow a bending of the finger, thus having but one motion
possible—that of separating the index from the other fingers
by the use of the abductor indicis, which is a y-shaped
muscle between the first joints of the thumb and index.
Being separate from all others, this muscle can be used for
an exact record. The marks in the curve represent the
height to which the weight was pulled each time.
Ten or twelve subjects were tried, though most of the
results were gained from four or five. The others were used
to verify the work. Some of the experiments were so painful
that they were not often repeated.
The two curves (see Plate 3), No. 3 taken January 19 and
No. 35 taken May 9, show the general effect of warming up
on one subject whom we may call G. They show, too, the
value of exercising a muscle regularly, since 530 grams at
first fatigued the muscle in about 95 seconds while in May
795 grams produced the same effect in 115 seconds. The
weight was pulled once every second at the swinging of a
pendulum. (These curves have been reduced but the general
character remains.)
Warming Up.
19
In the first curve (No. 3) it is seen that with G. the
curve falls quite steadily to the end. With G. and with
others it is found that this curve is as characteristic and uni¬
form as their signatures.
After the muscle was completely tired the weight was
removed (at line marked X) and a very light one put in its
place merely to keep the muscle active, for five minutes.
Then the same weight as used at first was replaced and the
second curve taken. In both of these cases, all of them in
fact that were tried on most of the subjects, there was not
room enough on the drum of the kymograph to record the
second curve and they were broken off before there was any
evidence of fatigue. In one instance G.'s warmed up curve
with 600 grams was continued a long time and then additions
made until he was pulling 1,075 grams, which he raised to a
good height till stopped by the operator. He could not move
more than 800 grams before the warming up occurred. With
this subject there was a feeling of muscular exaltation that
made it a pleasure to lift the weight after the warming up
occurred. It was found that this was true after he said that
he was tired out and did not feel able to go through the ex¬
periment. He noticed the same thing with studying. Others
have spoken of sitting down to study with a tired feeling
that almost persuaded them to give up the attempt, but be¬
ginning to work that feeling disappeared and the best work
followed without fatigue for two hours or more. That looks
as if the first feeling of fatigue is a ruse of nature to get out
of work. It only indicates that the system is still building
up or in the anabolic state. One cannot, however, judge by
his feeling what his warmed up curve may be. All but one
of the subjects showed this warming np phenomenon.
After marking the fact of warming up we attempted to
locate this increase of power. The first interesting point
noticed was that a general warming np, such as sparring,
running or g^eral active exercise in the gymnasium pro¬
duced the same warmed up condition of this small mnscle,
which was not used at all or very slightly in the general
20
Colorado College Studies.
warming. The curve is almost a reproduction of the second
part of No. 3.
Next electric stimulus was tried. At first the electrodes
were placed over marked points on the muscle. The results
were unsatisfactory. Since the current in such a case seems to
stimulate only a part of the muscle fibres, the slightest moving
of the hand or even a change in the position of the body or feet
would move the instrument or muscle enough to get a large in¬
crease of power at once, which at first seemed like a recovery of
power. Then we located the branch of the radial nerve which
supplies the motor power to this muscle and applied the elec¬
trodes to it. The result was a much larger amount of work
done and much more uniform results. The same attempt
was made to work the muscle a time, then give it five minutes'
warming up and then apply again the same stimulus to the
nerve as before. The results were not always the same and
varied much in different subjects. In no case, however, did
the curve after the warming up show a decided improvement.
In a few cases and in the subject G., who showed the most
constant improvement in the warmed up curve, there was
sometimes a slight improvement. This seemed, however, to
be entirely due to peripheral conditions. The flexibility of
the skin in the palm of the hand and about the index, the
natural stiffness or resistance about the joints that have not
been used in a certain way for a long time, might explain the
slight rise in the curve after these resisting elements had
been lessened or relaxed by use. This looked as if there
was nothing more than a slight improvement at most in the
muscle itself and the end plates of the nerves. See curve
No. 5, Plate 3.
Then there were many instances where the curve after the
electric warming up was less than before. In a few cases,
the same stimulus, applied to the nerve, could not raise as
large a weight after the first curve had been taken and a
period of five minutes had been given for rest and warming
up. On removing 150 grams the subject raised it to a good
height. The 150 were put back after a few successful pulls
of the lighter weight and the same condition prevailed as at
Warming Up.
21
first. The heavier weight, which in the first curve, before
the warming up, had been raised as high as the lighter weight
after it, could not be raised at all. This was done until we
were satisfied that the same stimulus to the nerve produced
less work after a time than at first and that the warming up
did not improve it.
This is in line with another experiment where the weight
was pulled by electric stimulus applied to the nerve every
two seconds during a long period of time—15 to 16 minutes.
The current was on one second and off one second. That
result may be seen on curve No. 13, Plate 1. The weight
was 525 grams and the current as strong as the subject could
endure. The pain decreased until the sensory nerves were
nearly or quite fatigued and failed to report any pain to the
brain, for after 10 minutes or so the current was scarcely
appreciable. In the curve there may be noticed an almost
rhythmical rise and fall. At first this would seem to contra¬
dict Lombard's work and give a " recovery" by electric stimu¬
lation. It would look as if there was a change caused by
fatigue in the muscle or nerve endings. It might be due to
a clogging of the contractile substances which worked them¬
selves clear again, or it might be due to an unconscious
assistance by voluntary effort. The curve is suggestive but
not decisive. There is no warming up but rather a loss of
power. Lombard's experiment was repeated here and his
results obtained. After voluntary fatigue the electric power
was used and then the voluntary, alternating, when it was
found that the power had returned though the muscle had
been worked all the time. To compare with that another
curve is shown. No. 16 (Plate 2), in which the same weight
was pulled voluntarily every other second and a distinct gain
of power or warming up appears. There was no fatigue but
a feeling of muscular exaltation in this abductor indicis at
the finish. This also shows that the warming up may be
gained without fatigue if moderate work is done at first.
An attempfwas made next to shut off the effect of in¬
creased circulation, thinking that the warming up might be
caused by an extra blood supply to the muscle. An Esmarch's
PLAT£ /. CURi^C /$.
ss
I
24
Colorado College Studies.
bandage was used to wind the arm, beginning with the fingers,
so that the blood was all driven back to a point near the
shoulder. A lighter weight was then used, 175 grams at
first, since the hand was rendered partially numb by the ex¬
periment. The effect was not all that we hoped but showed
one or two noteworthy results. Since the winding occupied
one or two minutes, the hand was. rapidly cooling before the
curve began. It was interesting, therefore, to note that the
first curve with each subject, taken with a bloodless arm, was
a facsimile of his normal curve taken with the blood in the
muscle. This was especially noticeable with one subject
whose curve was very characteristic, always having a rally
at a certain point near the finish. This rally appeared just
the same when the blood was shut off. Knowing one's curve
before, the curve with the bloodless arm could be identified
easily. After the first curve was taken and the weight could
not be moved again, the weight was taken off and three
minutes given for exercise of the muscle and warming up.
Then the same weight was attached. At first in each case it
could not be moved. Then with G. the power came back
and the weight was raised, and for a time his characteristic
warmed-up curve was recorded, which curve always differed
from the curve taken before the warming up. The pain in
the arm and hand became so severe that he begged to be
released. See curve No. 18, Plate 4. A recovery of power was
found with other subjects but not very marked except in one
case where a nearly normal power was gained for a few sec¬
onds, but the violent pain and numbness rendered the hand
useless. Sometimes after the first curve and five minutes'
attempt at warming up the hand could not be opened or
shut and no motion of the index was possible. After one
experiment with G., when the bloodless' hand had become
useless and no curve was possible after the five-minute rest
following the first curve, the bandage was removed and in one
minute the curve was taken and the usual warmed up curve
was the result. This shows that the warming had occurred
but the hand was stiff and cold so that the effect could not
be registered.
Warming Up.
25
One fact came out here in conflict with the teaching of
physiology in some colleges. The rate of fatigue was just
the same, with the circulation entirely shut off, as it was
before. Other experiments were made in this line but noth¬
ing valuable resulted.
The next experiment seemed to be more decisive. Sub¬
ject G. had been a subject for an hour or more in another
room learning nonsense syllables, where he had shown a dis¬
tinct warming up toward the end of the hour. His curve
was taken very soon after learning syllables and it was found
to be his warmed up curve, though he had been quiet physi¬
cally all the afternoon. The curve showed no flagging at all.
It was continued with no fatigue except the characteristic
rise and fall of a few centimeters seen on all of his warmed
up curves. This clue was followed. The subject was set to
adding for twenty minutes, at his most intense mental effort
and immediately afterward his curve was taken. It resulted
always the same way. The warming up was apparent and
his characteristic curve was registered. Learning of syllables
was tried again and proved to give a somewhat more com¬
plete warming up than the adding. See Plate 4, curve No. 45
for adding effect and No. 50 for memorizing effect.
In later tests a record was also taken of the respiration
and pulse. It was found in every case that the respiration
did not change much in rate and the changes in height are
due somewhat to motions of the body other than respiratory.
The pulse regularly falls from 4 to 6 beats a minute in
this experiment. It would seem thus that increased respira¬
tion or pulse has no share in the phenomenon of warming up.
It has been noticeable, too, in other experiments con¬
ducted in this laboratory where the subject was adding for
forty minutes or learning syllables, or alternately learning
and adding, that the pulse falls though there is a gain in the
time required to add or learn the syllables.
This experiment shows the following:
1. Warming up is general but not universal. One subject
always did his best work first. He shows no warming up in
mental work either. He can do his best studying the first
half hour and regularly decreases.
Warming Up.
27
2. Warming up is not gained with electric stimulation,
while it is gained, in those who show the phenomenon, by
voluntary effort.
3. A bloodless arm fatigues at the same rate as a normal
arm, and some recovery or warming up is possible even then.
4. This warming up may be gained from mental activity
and the effect of it shown in a muscle. It seems justifiable,
then, to locate the warming up in the brain cells.
Now, what happens in the cortex to produce this phenome¬
non? Four causes are suggested.
1. The use of a center may react on the local arteries and
increase the blood supply and nourishment of the nerve cells.
This is called hyperemia.
2. The stimulus may spread and involve a much larger
area. The automatic motor impulses which may be seen to
accompany any vigorous effort or new motion, may be
gathered and sent along these active channels.
8. The nerve cells may discharge more vigorously when
excited by products caused by the previous activity. That
is, it may be a case of auto-intoxication.
4. The amoeboid motion of the nerve cells as explained by
Golgi, Ramon y Cajal, Krapotkin and others, best explains
this warming up. According to them the dendrites, or tree¬
like branches of the nerves, which arise from the central end
of the nerve cell, tend to ball up or contract, when at rest, in
sleep, etc. When some stimulus is given, these expand and
make connections with their neighbors, and whole areas are
thus harnessed for activity which do not respond ordinarily.
In conclusion a few observations might be suggested.
Orators, athletes, students and working men often are aware
of this effect and practice mental or physical gymnastics, or
both, when about to make an unusual effort. Some orators
always excite themselves by recitation of thrilling literature
and by physical efforts before meeting an audience. The
effect is important on those who are influenced thus. It
means, if we take the fourth explanation above, that larger
areas of the brain are brought into activity. The question
28
Colorado College Studies.
of " second wind " is closely allied though not the same as
warming up. It is manifest that generally when people
speak of getting their second wind they mean they are
warmed up. This would apply always in all cases except
violent exercise, like running, where both phenomena are
present. There is no doubt that warming up gives better
control of the muscular system in running and other violent
exercise. The difficulty in breathing which passes away may
be merely an adjustment of the breathing to the increased
quantity of blood in the lungs caused by rapid muscular
activity.
Second wind, when spoken of in connection with study,
speaking, and muscular activity involving only a part or few
of the muscles, and in slow movements, is a misnomer. There
is no such thing. It is warming up. The subject who shows
no warming up in the above experiments, gets his " second
wind " in running. His physical system probably can exert
more power at fii'st than later, but he adjusts his breathing
to the demand.
The importance of warming up is greatly underestimated.
If one is properly trained so that he can warm up at will he
is able to use a tremendous power, even that of the insane or
frightened person, and then relax to rest and recruit the ex¬
hausted nerve cells.
Every one has great power, both mental and physical, that
he has never used. The insane laborer may become a poet
or musician of high order. What he can do at all, is in his
power any time, if he were so trained as to use it.
Lombroso, in his book "Genius and Insanity," tells of
various things which men of genius do to get their inspira¬
tion. A great crisis, national or individual, develops, as in
the case of the Polish boy, the latent possibilities in one's
character and makes the Lincoln or the Grant out of the
country lawyer or the tanner. The person who cannot warm
up can never meet a great occasion. The person who warms
up greatly and yet controls his activity may do anything
within human possibilities. Not only the large motor areas
of the brain come to aid the part in central use, but the sensory
Warming Up.
29
areas which coincide with the motor in location in the brain
are also in active coSperation. Dr. Richard H. Storrs,
who was wont to pound his own upholstered pulpit, in a
grand burst of eloquence struck the marble desk where
he was preaching and broke two bones in his hand, but was
unconscious of the fact till the sermon was over.
Napoleon referred to the same thing when he said that
the fate of battles was the result of an instant of latent
thought. " The decisive moment appeared, the spark burst
forth and one was victorious." The deep desire in the child
and adolescent and in grown people to such an extent as was
shown last year by the thousands who gathered in all cities
to get the news from Carson City, may be a natural hunger,
perhaps depraved in adults, for such excitement as will push
into function new and larger brain areas.
Education should mean a culture of one's potential ener¬
gies that they may become actual when occasion demands.
The great public schools in England have made men as per¬
haps no other schools have done in the past century. Why?
May not one reason be that they have in peculiar ways taught
their students to rise to the occasion and have furnished in¬
spiration which has made possible such men as Wellington
and Gladstone. The application of this problem may be
wide and important if carried into all educational work. In
order to do a great work we must have a highly developed
brain, which can be thrown into activity quickly and as a
unit of power.
«
EQUATIONS OF MOTION OF A VISCOUS LIQUID.
PEARL EUGENE DOUDNA, B. A., M. A.
Historical Introduction.
Two and a half centuries B. C., Archimedes (287?-212)
wrote a work entitled De lis Quae Vehuntur In Humido.
He maintained that every particle of a fluid mass, when in
equilibrium, is equally pressed in every direction. The laws
and properties of liquids were investigated by this ancient
mathematician sufiiciently to enable him to devise a hydro¬
static means of determining the purity of the precious metals.
He made a further practical application of the results of his
studies in this direction by the invention of the screw engine,
or the Archimedean screw.
The Alexandrian School is accredited with the construc¬
tion of a few hydraulic machines, such as the siphon and the
force pump. However, fluid motion was probably first studied
by a Roman, Sextus Julius Frontinus, inspector of the public
fountains at Rome in the reigns of Nerva and Trajan, about
the close of the first century A. D. In his work entitled
De Aquaeductibus Urbis Romae Commentarius, is found a
description of the great aqueducts at Rome. Frontinus con¬
structed five new aqueducts, making in all fourteen. He also
describes the methods nsed in determining the amount of
water discharged from ajutages and the methods of dis¬
tributing the water of the aqueducts and fountains. He
observed that the amount of water discharged depends upon
the height of the water in the reservoir above the orifice as
well as the area of the orifice.
Fifteen centuries later Castelli (1628) advanced the theory
that the velocity of discharge is proportional to the height
of water in the reservoir above the orifice. Torricelli, a con¬
temporary of Castelli, observing that a small jet of water
rushing from an ajutage rises to a height almost equal to
Equations of Motion of a Viscous Liquid. 31
that of the water in the reservoir, concluded that the velocity
of discharge is equal to the velocity which the water would
acquire by falling freely through a distance the same as the
height of the water above the orifice. As a result of this
observation he obtained the correct relation between the
velocity of discharge and the head of water (1643).
Mariotte (1620?-l684), the author of a posthumous work,
entitled Traitd duMouvement des Eaux et des Autres Fluides
(1686), made extensive use of the theorem of Torricelli. He
seems to have been the first to attempt to reconcile theory
and experiment by attributing the retardation to friction.
The filaments sliding along the surface of the pipe were sup¬
posed to be retarded and other filaments having a greater
velocity than those near the surface were retarded by rub¬
bing against the slower ones. The retardation was supposed
to be proportional to the distance from the axis of the pipe.
Guglielmini, a contemporary of Mariotte, devoted himself
to the study of the motion of the water in rivers and canals.
He assumed that every particle in a vertical section moves
with a velocity equal to the velocity of discharge from an
orifice at an equal depth below the surface of the water, and
explained the discrepancy between theory and fact as due to
transverse currents caused by the irregularities in the bed of
the stream. Later, however, when Mariotte showed that the
same retardation takes place in a glass tube, where it cannot
be explained by cross-currents, Guglielmini accepted the ex¬
planation of the French philosopher, but also maintained that
viscosity had considerable to do in retarding the motion.
In the latter part of the seventeenth century Varignon
(1654-1722) gave to the Academic des Sciences de Paris a very
natural and plausible explanation of the relation existing
between the velocity of discharge and the head of water.
Having remarked that when water flows from a cylindrical
vase (vessel) through a small orifice in the bottom the water in
the vase moves with a very slow and sensibly uniform motion
for all the particles, he concluded that there is no accelera¬
tion and that the portion of the fluid escaping each instant
receives all its movement from the pressure produced by the
32
Colorado College SxuDiES.
weight of the column of fluid having the area of the orifice
as a base. Therefore its weight, which is proportional to the
area of the orifice multiplied by the height of the fluid in the
vessel, must be proportional to the quantity of motion engen¬
dered in the particles which escape through the orifice each
instant. Continuing this analysis, he finally arrives at the
theorem already established by Torricelli by an entirely dif¬
ferent method.
The investigation of the flow of water in rivers attracted
considerable attention in Italy, probably on account of the
extensive landscape gardening. Besides Guglielmini, who was
inspector of rivers in Milanese, Marquis Polini deserves men¬
tion in this connection. In 1(595 he wrote De Motu Aquae
Mixta, and in 1718 another work concerning the flow of
water through orifices and short tubes.
Newton (1642-1727) investigated the effects of friction
and viscosity in diminishing the velocity of running water.
In book 2, § 9, of the Princtpia, he offers the following
hypothesis: The resistance which arises from the viscosity
of a fluid, other things being equal, is proportional to the
velocity with which the particles separate from each other.
This may be said to be the fundamental principle underlying
all that part of hydrodynamics which deals with viscous
fluids. The vena contracta as well as the oscillation of waves
seems to have been considered first by Newton.
Daniel Bernoulli published his Hydrodiinamica, Sive De
Viribtts et Motihus Fluidorum Commentarii, in 1788, in
which he bases his theory upon the suppositions that the
surface of a fluid contained in a vessel which is being emptied
by an orifice remains always horizontal and that the hori¬
zontal strata always remain contiguous to each other, and
that the particles descend vertically with a velocity inversely
proportional to the horizontal section of the reservoir. His
principle was not acceptable to his contemporaries, conse¬
quently John Bernoulli and Maclaurin each attempted to
solve the problem by independent methods but did so with¬
out marked success.
Jean-le-Rond D'Alembert (1717-1788), aided by the dis¬
coveries of Euler (1707-1783), took the first great step in
determining the general equations of motion of a perfect
Equations of Motion of a Viscous Liquid.
33
fluid. " When generalizing James Bernoulli's theory of
pendulums he discovered a principle of dynamics so simple
and general that it reduced the laws of motion of bodies to
that of their equilibrium. He applied this principle to the
motion of fluids, and gave a specimen of its application at
the end of his Dynamique in 1743. It was more fully developed
in his Traits Des Fluides, which was published in 1744,
where he resolves, in the most simple and elegant manner,
all problems which relate to the equilibrium and motion of
fluids. He makes use of the very same suppositions as Daniel
Bernoulli, though his calculus is established in a very differ¬
ent manner. He considers, at every instant, the actual motion
of a stratum as composed,of a motion which it had in the
preceding instant and of a motion which it has lost. The
laws of equilibrium between the motions lost furnish him
with the equations which represent the motion of the fluid.
Although the science of hydrodynamics had then made con¬
siderable progress, yet it was chiefly founded on hypothesis.
It remained a desideratum to express by equations the motion
of a particle of fluid in any assigned direction. These equa¬
tions were found by D'Alembert from two principles: first,
that a rectangular canal, taken in a mass of fluid in equi¬
librium, is itself in equilibrium; second, and that a portion of
fluid, in passing from one place to another, preserves the same
volume when the fluid is incompressible, or dilates itself accord¬
ing toagiven law when the fluid is elastic. His very ingenious
method was published in 1752, in his Essai Sur la Resistance
Des Fluides. It was brought to perfection in his Opuscules
Mathematiques, and was adopted by Euler." Philosophers
had attempted in vain to determine the laws of fluid motion
independent of all hypotheses. However, the method of
fluxions proved inadequate to the purpose, and it was only
after Euler had contributed to science his calculus of partial
differences that the object was reached. D 'Alembert first
applied the new calculus to the motion of water, and he and
Euler both succeeded in obtaining equations of motion for a
perfect fluid restricted by no particular hypothesis.
Chevalier Dubuat, a French engineer, published in 1786
a very satisfactory theory of the motion of a fluid, based upon
the experiments of himself and others. " He considered that
if water were a perfect fluid, and the channels in which it
34
Colorado College Studies.
flows inflnitely smooth, its motion would be continually ac¬
celerated, like that of bodies descending on inclined planes.
But since the motion of rivers is not accelerated, and soon
arrives at a state of uniformity, it is evident that the viscosity
of the water and the friction of the channel in which it de¬
scends must equal the accelerating force. Dubuat, therefore,
assumes it as a proposition of fundamental importance, when
water flows in any channel or bed, that the accelerating force
which obliges it to move is equal to all the resistances which
it meets with, whether they arise from the viscosity or from
the friction of the bed."
In 1779 Abb6 Bossut conducted very extensive investiga¬
tions to determine the amount of retardation in pipes due to
adhesion and friction. He reached the conclusion that with
pipes of the same length the discharge is proportional to the
diameter, and when the diameters are equal the discharge
is inversely proportional to the square root of the length.
The general equations of motion are so complex that little
could be done with them. This resulted in the numerous
efforts which were made by one class of investigators, such
as Dubuat, Bossut and Prony, to develop by experiment sim¬
pler formulas for the velocity of running water. However,
the more theoretical mathematicians, among whom were
Lagrange, Laplace, and Poisson, endeavored to obtain solu¬
tions for the equations of D 'Alembert, and thus solve the
various problems of hydrodynamics. These men, together with
other eminent mathematicians of both France and Great
Britain, devoted much time to the investigation of waves and
tides.
Navier (1785-1836) was probably the flrst to offer equa¬
tions of motion for a viscous fluid (1822). He bases his in¬
vestigation upon the following suppositions: The fluid is com¬
posed of ultimate molecules, acting upon each other with forces
which, when the fluid is at rest, are functions simply of the
distance, but when the molecules recede from or approach
each other are modified by this circumstance so that two
molecules repel each other less strongly when they are reced¬
ing and more strongly when they are approaching each other
than when they are at rest; and the alteration in the attrac-
Equations of Motion of a Viscous Liquid.
35
tion or repulsion is supposed to be proportional to the veloc¬
ity with which the molecules, separated by a given distance,
are approaching or receding from each other. A second sup¬
position involves the symmetrical arrangement of the particles.
Navier dealt only with an. incompressible fluid, and arrived
at the following equations:
If dp __ ^ /du' du^ didX \_Su
P \da: \dx^ dy' dzy) 8t
and the other two can be written by making similar changes
in the corresponding equations for a perfect fluid. A is a
coustaut, depending on the nature of the fluid. The other
terms are the same as those used in the following pages.
Poisson (1781-1840) derived equations not only for an
incompressible fluid, but also for an elastic fluid in which
the change in density is small. He treated the subject from
the staudpoint of an elastic solid, supposing the fluid to be
continually beginning to be displaced like an elastic solid,
and continually rearranging itself so as to make the pressure
equal in all directions, as is the case with a fluid at rest. His
equations are written thus:
^ 1/dp ^fdv^ did dn\ d/du ^dv _^dw\\_Su
/> \da; \dx^ dy^ dz') dx\dx dy dz) J H
with the other two to correspond.
For an incompressible fluid these agree with those ob¬
tained by Navier, since in that case the expression for cubical
expansion disappears. It is to be noticed that both the fore¬
going methods involve a consideration of the ultimate mole¬
cules of the fluid.
Barr6 de St. Venant (1797-1886) flrst succeeded in ob¬
taining the equations independent of any consideration
of the' ultimate molecules. He attempted to connect the
oblique pressures in different directions about a point with
the differential coefficents etc., which express the rel-
dx dy
ative motion of the fluid particles in the immediate neighbor¬
hood of the pflint, by assuming the tangential force on a plane
passing through the point to be in the direction of the prin¬
cipal sliding along that plane. He then employs theorems
86
Colorado College Studies.
by Cauchy, connecting the pressures in diflferet directions in
any fluid, to show that the tangential force in any direction
along a plane is proportional to the sliding along the same
plane resolved in the same direction. He published this
theory in 1843.
In 1845 G.G. Stokes derived the same equations as Poisson,
but found that A=dB. He based his investigation upon
three principal hypotheses: "First, that the difference between
the pressures on a plane in a given direction passing through
a given point P of a fluid in motion and the pressure which
would exist in all directions about P if the fluid in its neigh¬
borhood were in a state of relative equilibrium depends only
on the relative motion of the fluid immediately about P; that
the relative motion due to any motion of rotation may be
eliminated without affecting the differences of the pressures
above mentioned." (Stokes.) He then arrives at the con¬
clusion that the stresses due to viscosity are functions of the
rates of strain. After speculating as to the molecular consti¬
tution of the fluid, he arrives at the hypothesis that these are
linear functions. This is his second hypothesis. For gases
he introduces a third: " When a gas is expanding equally in
all directions, the stresses P, Q and R are the same as if the
fluid were frictionless." * # * * In his report to the
British Association in 1846 "On Kecent Researches in Hy¬
drodynamics," Stokes claims that the principal feature of his
investigation consists in eliminating from the relative motion
of a fluid about any particular point the relative motion which
corresponds to a certain motion of rotation and examining
the nature of the relative motion which remains; and that
the method employed does not necessarily require the con¬
sideration of the ultimate molecules.
The second assumption of Stokes is not altogether satis¬
factory, since it rests upon the supposition that the velocity
is small.
In 1861 O. E. Meyer derived the ordinary equations if
B=0, which, according to other investigators prior to this
time, are true only for an incompressible fluid.
Equations of Motion of, a Viscous Liquid.
37
He begins his investigation after some preliminary con¬
siderations with the following statement: "The internalfric-
tion of a fluid takes place between the different strata of the
same fluid, and is proportional to the differential coefficient
of the velocity along the normal to the plane separating the
strata." But this hypothesis explains only six of his nine
initial expressions. For instance, if we take the three initial
expressions for the retarding forces parallel to the x axis, viz.,
du , ,
—n — dij dz,
dx
dit , ,
—11 — dz dx,
dy
du , ,
—n — dx dy,
dz
the second and third readily follow from the hypothesis, but
the first has no definite meaning, unless we extend his hy¬
pothesis, as W. M. Hicks has interpreted it in the British
Association Report for 1881, so that it reads: " The friction
on a small plane in a given direction in the plane is propor¬
tional to the rate of variation perpendicular to the plane of
the component of the velocity in the given direction, whilst
there is a normal part proportional to the rate of variation
perpendicular to the plane of the component perpendicular
to this plane."
The subject has been investigated by Stefan (1862), and
later by Maxwell, Levy, Klutz, and Butcher, without adding
materially to what had been done already.
However, the work of Maxwell resulted in the determina¬
tion of the constant called the coefficient of viscosity. Fol¬
lowing Maxwell, numerous experiments have been made for
the purpose of determining the value of the coefficient
of viscosity. Helmholtz, Piotrowski, Maxwell, Meyer, and
Poissenille may be named as having made the most elaborate
series of experiments.
Lamb, in ^is Treatise on Fluids (1879), derives the equa.
tions of motion for a viscous fluid by a method based on
those of St. Venant and Stokes. Basset, in 1888, published
38 CoLOEADO College Studies.
A Treatise on Hydrodynamics, in which he uses Stokes'
method. Both authors accept the second hypothesis of Stokes,
so that we have no assurance that their equations hold, except
in the case of slow motion. Both fully realize this, and re¬
stricted the application of their results accordingly. Of all
methods so far, that of Stokes has received the most general
approval.
In the following paper we have derived the equations for
the motion of a perfect fluid in order that we might extend
the same methods as far as possible in obtaining the equa¬
tions for a viscous liquid (the discussion is limited to an
incompressible fluid, or liquid). The second section is
devoted to the consideration of a viscous liquid. The dis¬
cussion is based upon the definition of the coetflcient of vis¬
cosity as agreed upon by experimental physicists. Then by
comparing the motion of a viscous liquid with that of a perfect
liquid we are enabled to give a deflnite meaning to all nine
of the initial expressions obtained by Meyer. To obtain the
equations referred to cylindrical and spherical coordinates we
have not used the method of transformation, but have derived
them by analysis similar to that used in determining the
equations when referred to rectangular coordinates. By this
method a deflnite meaning attaches to each term in the result¬
ing equations. This part of the subject is given in Sections
8 and 4, and will appear in a later issue of the Colorado Col¬
lege Studies. The essential features of Sections 1 and 2
were completed before April 1,1895; of Sections 3 and 4 before
June 1, 1896. The notes at the end of Section 4 were added
during the spring of 1897.
Works consnlted in preparing this historical sketch:
Encyclopaedia Britannica, ninth edition; subject. Hydromechanics.
British Association Reports. Report on the Recent Researches in Hy¬
drodynamics, by Stokes, ISiti; by Hicks, 1881.
Works on Hydrodynamics, by Lamb and by Basset.
Pamphlets on Internal Friction of Fluids, by O. E. Meyer.
Stokes' Papers.
Newton's Principia.
Penny Encyclopaedia; subject. Hydrodynamics.
Cajori's History of Mathematics.
Lagrange's Mechanique Analitique.
Equations of Motion op a Viscous Liquid. 39
Derivation of Equations.
Section I.—Equations of motion of a perfect fluid.
D'Alembert's Principle: Since D'Alembert's Principle is
used so frequently in what follows, it may be well to say by
way of explanation of this principle that its use means the
equating of
Impressed Force—Pressure—Expressed Force
to the forces lost through friction.
An Ideal Fluid.—With this as with other problems, it
is easier to consider first the ideal condition. An ideal fluid
is one in which there is no friction; the particles move by
one another without causing any mutual retardation; hence
without any loss of energy.
The Derivation of the Equations of Motion of a Perfect
Fluid.—To derive the equations of motion of a perfect fluid
is a comparatively easy matter.
Let A D {Fig 1) represent an element of such fluid; x,y,z
be the coordinates of the point A; AG, A B, and A H equal
to dx, dy, and dz respectively; X, Y, and Z the impressed
forces in directions x, y, and z-, and «, v, and w the velocities
40
Colorado College Studies.
in the same directions; and finally let p represent the pres¬
sure at the point (x, y, z) and m the mass of the element.
From the conditions of the problem
u=f{x,ij,z,t)
and it follows immediately that
du fill , flu , flu , du ,
—=-- + u t-v—+2C—=Jx-
St dt dx dy dz
This last is an expression for the effective or expressed force
dv
in the direction of the x axis. In a similar notation —, orfy
St
and —, or fz represent the effective forces in the direction
St
of the y and z axes respectively.
The total impressed forces are mX, mY, and mZ; the total
effective forces mf^, mfy^ fnfz; the pressures on the faces
AC, AE, and AF are p dy dz, p dy fix, and p dx dz respec¬
tively; on the faces opposite these the pressures are p dy dz-f
— dx dy dz,pdy dx+^dz dy dx, andjp dxdz-\- — dydx dz.
dx dz dy
The excesses of pressure on the opposite faces are:
^ dx dy dz, — dx dy dz, and — dx dy dz.
dx dz dy
Since the hypothesis excludes the possibility of any loss
through friction, we have now considered all the forces in¬
volved. Equating separately the forces acting in the direc¬
tion of each axis by D'Alembert's principle, we obtain the
following equations:
mX—mfx —— dx dy dz=0
dx
niY—mfy — —- dx dy dz=0
dy
mZ—mfz — — dx dy dz=0
dz
Substituting for m its value p dx dy dz in which p repre¬
sents the density of the fiuid, and then dividing by dx dy dz,
the resulting equations are:
Equations of Motion of a Viscous Liquid. 41
Xp-U-^=0
ax
Yp-fyP-^ = 0
dy
Zp-f,p-^=0,
dz
or as usually written:
„ dp Su
ui.
pdx H
Y—
pdy St
Z— ^P
pdz St
So far we have obtained three relations between the five
quantities u, v, w, p, and p. When these equations are used
in application to an incompressible fluid, p is constant; but
when gases are under consideration, a fourth equation is
supplied by Boyle's Law,
p=kp.
Continuity.—The condition of continuity furnishes a fifth
equation. If the fluid be continuous, then the increase within
a given space during any given time must equal the excess
of inflow over outflow across the boundaries in the given
time.
The mass of fluid contained by the element at any mo¬
ment, is p
and its increase in the time dt is
— dt dx dy dz.
dt
The flow over the surface dy dz in time dt is
u p dt dy dz
and the flow over the opposite face is
u p dt dy dz+ dt dy dz dx,
^ dx
giving an increase in the element of
dt dx dy dz.
dx
42
Colorado College Studies.
Similarily the increments in the directions of the y and z
axes are found to be
^ dt dx dy dz
dy
dt dx dy dz.
dz ^
Equating the whole increment to the partial increments and
dividing by dt dx dy dz, we obtain
dp d{up) ^d{vp) ^d(iop)
dt dx dy dz
But for an incompressible fluid, p being constant, this
becomes
du_^dv_^dw_Q
dx dy dz
Section II.— The Equations of Motion of a Fiscoms Fliiid.
Having determined the equations of motion of a perfect
fluid when referred to rectangular coordinates, we will now
consider a viscous fluid. This consideration will combine
those forces already dealt with in the case of a perfect fluid
and the forces lost through internal friction.
The problem is to determine the relations existing between
these lost forces and the velocities.
Coefficient of Viscosity.—It is necessary at this point to
It AE D It represents the initial position of an element
Equations of Motion of a Viscous Liquid.
43
subjected to a shearing force exerted parallel to the planes of
the strata, e. g. plane ATRB, such that the element takes
the form AMG R, the coefficient of viscosity is defined as
the ratio of the shearing stress to shear per unit of time.
Putting this definition in the form of an equation, we have
shearing stress _
shear per unit of time
in which fi is the coefficient of viscosity; or shearing stress
=fi X shear per unit of time. Let u be the velocity in the direc¬
tion of A Bj and the point A be located by x, y, z; the sides
of the element be dx, dy, dz. Then
u=f{x, y, z)
du
—=f^{x, y, 2:)=rate of normal displacement
dy
along y. This force acts upon the surface of the element
dx dz. Hence the shearing force on this surface is
F=ti—dx dz.
dy
The force on the opposite face is
F^=!x— dx dz+fjt^^dx dz dy.
dy dy'
The difference of the forces on the opposite faces of the
element considered is the retarding force due to the viscosity
of the fluid.
Derivation of the Equations.—Sufficient has now been said
to proceed to the derivation of the equations. We shall take
up this problem in much the same way that we did the prob¬
lem of a perfect fluid. But this new element of viscosity
must be taken into account. It is evident that our equations,
when derived, must be the same as those already obtained
for a perfect flui^ with terms attached to account for the
retardation due to viscosity. For if in our new equations
be equated to zero the equations of a perfect fluid must
remain.
44 Colorado College Studies.
Forces to he Equated.—The forces to be equated are
Impressed force,
Pressure,
Effective force, and
Retarding force, or force lost,
which give, when equated,
impressed force—pressure—effective force=
—retarding force,
or, in the more usual form,
impressed force—pressure+retarding force=
effective force.
It is to be noticed that the sense in which the retarding
force is taken is opposite that in which the impressed force
is taken.
Rectangular Co-ordinates.—Take an element PB, the co¬
ordinates of the point R being x, y, z and the dimensions of
the element being dx, dy, dz.
Equations of Motion of a Viscous Liquid. 45
Suppose the velocity uniform in the direction of x. Then
any parallelopiped, such as AB, would move as a solid; but
the element is composed of a great many such parallelepipeds.
If the velocity in the direction of x varies as we pass from
R to K, the layers in slipping by each other will produce
mutual retardation. The rate of change in u along the nor¬
mal to its direction is
dti
dy
From the definition of viscosity it follows that the shearing
force upon the face SB \&
du , ,
ft — ax az,
dy
and that upon the opposite face is
du , , , d^u , , ,
ft— dx dz+ft— dx dz dy,
dy df
indicating a loss of force within the element equal to
d^u - - ,
ft dx dy dz.
df
In a similar manner we find the retardation upon the
face dy dx to be
du , ,
ft — dx dy,
dz
and on the opposite face to be
du , , , d^u , , ,
ft— dx dy-\-u— dx dy dz,
dz dz^
showing a loss within the element of
d'u , , ,
ft — dx dy dz.
dz^
All of the loss within the element is now accounted for,
provided the v^ocity in the direction of x is uniform. It
remains to examine the effect of an accelerating force along
the axis x. To simplify the problem, suppose the motion two
46
CoLOKADO College Studies.
dimensional. In this case it is necessary to consider only a
section, such as .4C (Fig. 6).
FIG. 6.
Suppose under certain conditions a certain motion exists
at B. If the fluid is perfect a certain amount will flow into
the parallelogram .4C across the line AE, due to the accelera¬
tion of the velocity u. ED represents the whole increase
of inflow at E over that at A.
But
ED=AB-DC.
AB
u
DC u
AB, and that across DC.
AB-DC
, u being the velocity across
By composition
u—u
AB
which represents the distance of inflow at E when a unit
length of AB is considered. The time of inflow is di, hence
AB—DC —u
AB dt u^dt
gives the rate of displacement in the direction of .v.
dt\ J dt\ td) dt\ u + du)
did
\ u u' w
_ 1 /du did ^did did
did du
u'
i-slo.)]
+ etc
dt\ii vd id id
Since this series converges very rapidly, unless the in-
)
Equations of Motion of a Viscous Liquid. 47
crease in motion is very great all of the terms except the first
may be dropped. This gives
1 /<hi\__du
dt\ u J dx
The retarding force on the face dy dz is
du , ,
/^ — dy dz,
dx
and on the opposite face
du , , , d'u , , ,
IJ. — dy dz+p. — dy dz dx,
dx dx'
showing a loss for the element of
d'u , , ,
P — dy dz dx
dx' ■'
when the fluid is viscous.
The retardation in the direction of the x axis must equal
the retardation of inflow, for otherwise there would be a dis¬
continuity.
It is necessary to extend this principle to the case where
the inflow is across two faces instead of one.
G
H
K
FIG. 7. E
AB. AD—HI. /J^=total areal increase of inflow.
AB.AD
u
HI. IJ u
AB. AD—HI. IJ u^—u
AB.AD dt
iddt
= rate of inflow.
But
id —u 1 1
dt u' dt\
u
uAdu,
48
CoLOBADO College Studies.
Expanding this and neglecting, as before, all terms except
dxi
the first, we get — for the rate of infiow.
dx
This shows that the lost forces obtained for two dimensional
fiow hold in the case where the inflow is over two faces. This
could have been concluded without the above proof, for the
amount flowing in is fixed, and it is immaterial whether the
fiow is all in the direction of z or partly in the direction of z
and partly in the direction of y.
The forces in the direction of the y and z axes can be ob¬
tained in the same way.
It is to be noticed that a force element of the second order
is neglected if, for example, there is a normal increase in the
velocity u, for in that case the inflow will be accelerated.
Equating the forces found and writing the remaining two
symmetrical equations, we have
dp _Su _iJ./d'u^d^u d'^u\
pdx St p\dx' dy^ dzy
Y dp _Sv p/d^v d'v
pdy St p Xdx^ dy' dz^j
Y dp Sw p^d'w ^d^w d^w\
pdz St /) \ dx^ dy^ dz^ J
(To he Continued in Volume VIII.)
Colorado Colleg^e
Studies.
VOLUME Vlll.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLO.
1899.
[Issued in April, 1900.]
'61^,1
_ , ,0. T 1 ^
X
V.S
CONTENTS.
Page.
( 1) Ec^nations of Motion of a Porfect Licjiiid and a
Viscous Liquid, when Referred t(j Cylindri¬
cal and Polar Coordinates, (Part II, con¬
tinued from Vol. VII, p. 48 ) 1
Prof. P. E. Doudna.
(2 I The Capricorns, Mammals of an Asiatic Type,
Former Inhabitants of the Pike's Peak Re-
f>;ion, 21
Dr. F. W. Cragin.
(8) Buchiceras ( Sphenodiscus) Belviderensis and
its Varieties, 27
Dr. F. W. Cragin.
(4) The Number Concept, i>2
Dr. Florian Ca,tori.
EQUATIONS OF MOTION OF A PERFECT LIQUID
AND A VISCOUS LIQUID, WHEN REFERRED
TO CYLINDRICAL AND POLAR CO-
ORDINATfisS X > S ^ -H-V
v>F
by p. e. doudna,* a. m. _ , rr- ^ . r <
, At^-b-i-hN^SX.
(Continued from Vol. VII, p. 48.)
Equations of a Perfect Liquid.
Cylindrical Co-ordinates: The equations of motion of
a perfect fluid when referred to cylindrical coordinates may
be derived from those already obtained for rectangular co¬
ordinates by transformation. The following, however, is a
more satisfactory method in so much as it gives a definite
interpretation to each term appearing in the resulting equa¬
tions. Moreover, the method to be applied in the derivation
of the equations when referred to cylindrical coordinates and
polar coordinates forms the basis of several important prin¬
ciples involved in the derivation of the equations of motion
of a viscous fluid referred to the same systems of coordinates.
The velocities u, v, w, and the impressed forces X, Y, Z
have the directions of r, 0, and z, respectively; v is angular
velocity.
Xp r do dz (/r=impressed force in the direction,of r.
* Died at Colorado Springs, January 6,1900.
2 Colorado College Studies.
• •
— pr do dz dr=effective force in same direction due to
St
an acceleration in the velocity u. The velocity v through
centrifugal force contributes to the effective force in this
direction , j j *
—V p r do dz dr.*
The velocity w can have no influence upon the forces in
the direction of r.
—— rdo dz dr
dr
is the difference in pressure on the two faces C K and D M.
Equating by D'Alembert's Principle, we have
Xp rdo dz dr—^^rdo dz dr -p rdO dz dr+v'p r'do dz dr=0.
dr St
Dividing by p rdo dz dr and transposing, this equation be¬
comes
dp Su
X —= uV.
pdr St
Similarly for the forces acting in the direction of 0
Yp rdo dz dr=impressed force,
r—p rdo dz d?'=effective force
St
contributed by acceleration in v.
dif}
——rdo dz dr=difference in the pressures on
rdo
the opposite faces. But there is still another resulting force
acting in this direction due to the fact that while a particle
* If there were no motion in the direction of r, a force directed
toward the center would be necessary to maintain the configuration of
the element. This force would be
dp
v'p r'do dz dr—~ rdO dz dr.
dr
Since motion along r is in a straight line, it follows from Newton's sec¬
ond law that, if the velocity in that direction is uniform, the above
relation still holds.
If the motion in this direction is accelerated,
— P rdo dz dr=Xp rdO dz dr+ifp r^dO dz di—— rdO dz dr,
St dr
Su , J dp
or —=X+vr—
St rdr
Equations of Motion.
8
is being carried in the direction 6 it is also being carried in
the direction of r by the velocity u; consequently, at the end
of the time dl it will have fallen behind by an amount equal
to
{r-\-dr) do—rdo or dr dO.
From physics, s=\ fV
._2 s
7-y,
where/= acceleration, s the space described, and t the time.
Substituting,
dr do
f=z =2 iiv*
dr
which is the force due to this fall, multiplying by prdO dr dz
we get for the total of this force
2 uv prdo dr dz.
The velocity along 2 as before contributes no component to
the forces in this direction. Equating the forces found and
simplifying, we get
T-, dp Ov , n
^ —r—\-2.uv.
prdo ot
Neither u nor v can contribute a component to the forces
acting in the direction of the 2 axis, therefore the equation
of these forces will be identical with the corresponding equa¬
tion for rectangular coordinates.
* If from an elevation on a uniformly rotating body a particle falls
towards the axis of rotation it constantly gains angular velocity with¬
out the application of any force in the direction of o- This is true of
falling bodies on the surface of the earth. A rotating body, if contract¬
ing, would increase its angular velocity. To maintain the motion
uniform under such conditions, a force must act in the direction op¬
posite to the direction of motion. This force is
* dp
2 uvp rdo dz dr —rdO dr dz.
rdo
If such a force were acting the configuration of the element would be
maintained. If the motion were from instead of toward the center an
opposite force would be necessary to keep the velocity uniform or to
maintain the configuration of the element.
Colorado College Studies.
Collecting the results just obtained, we have
(Jp _ 'hi
X-
pdr 'U
—vr,
dp '5(J „
Y — = r 1-2 nv,
prd 0 <U.
^ dp _'ho
pdz 'U
The equation of continuity is
d(ur) , dv , rdw
\-v ' ■
dr
do dz
=0.
It is unnecessary to derive this last equation, since the
method by which it is obtained is identical with that used
to obtain the similar equation referred to rectangular co¬
ordinates.
Spherical Co-ordinates.—Angle WOF (in Fig. 9) = ^ and
QOD=<p. Let u, V and to represent the velocities in the direc¬
tions r, 0 and <p respectively, v and w being angular; X, Y
and Z are the symbols for the corresponding impressed forces.
The mass of the element F3I is
p dr rdo r s\nd d<f=m.
Equations of Motion.
5
Then Xm= impressed force in the direction of —m ■=
H
effective force due to the acceleration in u; the centrifugal
force —rv^m (see note, p. 2) results from the velocity v; the
centrifugal force contributed by w is —r sin Ow'^m (see note,
p. 2) in the direction of OD, and this gives the component
—r sin ^0 w^m along the radius vector r; — dr rdO r sin 0 d<f>=
dr
the difference in pressure on the two opposite faces.
Equating and transposing as before
dp ^11 i ■ in 2
X —= rv—r s\n Ow .
pdr St
With reference to the direction of 0, we have
E"m=impressed force,
r—j?j=efifective force due to the acceleration
St
in angular velocity v.
dt)
/>-^TO=difference in pressure on the opposite faces.
rdO
Since as a particle moves from to it is carried by u the
distance ER, it falls behind by an amount equal to dr do,
which, when expressed in terms of force, is equivalent to
2 uv (see note, p. 3).
Multiplying by mass,
2 uv m
represents the component of effective force contributed by
the combined action of u and v; iv cannot exert an effective
force such as this, since the particle always moves in the same
parallel, but it does exert a centrifugal force in the direction
of 6, or rather there is an effective component of the centri¬
fugal force acting in the direction of 0 due to w. We already
know (see abov«) that the centrifugal force due to w along
OD is
—r sin 6 io\
Since the tangent to EF at E makes an angle 0 with OD, the
component of
— r sin 0 w'
6
Colorado College Studies.
along the tangent is
—r sin 0 cos 0
Multiplying by mass, we have
—r sin 0 cos 0 vfm.
Equating and simplifying, the resulting equation is
Y—+ 2 uv—r sin 0 cos 0 vf.
prd0 8t
The forces along the <p co-ordinate are
impressed force,
sin <'r—m=effective force due to the accelera-
81
tion of angular velocity w,
dt)
— iR=difference in pressure on the op-
pr sin 0d<p
posite faces.
Since by the combined action of u and w a particle falls
behind , . „,
dr sin 0d^,
which, converted into terms of force, gives
2 sin 0 wu (see note, p. 3),
we obtain a total force contributed by the combined action
of these two velocities equal to
2 sin 0 wu m;
V also carries the particle through the distance EF, and since
the line FK is shorter than EH there will be a resultant
effective force due to the combined action of v and w.
EH=r sin 0 df,
FK=r sin {0—d0) d<p,
=rd<p (sin 0 cos d0—cos 0 sin do).
Substituting, for cos dO, 1 and, for sin dO, d0
FK—rd<p sin 0—rd<p cos 0 d0,
EH—FK=rd'p cos 0 do, or the distance through
which the particle may be said to fall under the combined
action of it and v. This is equivalent to a force
2 r cos 0 wv,
or for the mass of the element,
2 r cos 0 wv m.
Equations of Motion. 7
By equating and simplyfying, we obtain the third equation,
Z =r sin —+2 sin 0 m(;+2 r cos 0 vw.
pr sin Od<p St
Equation of Continuity.—The increase in the element for
time dt is
— 7^ sin 0 d<p dr dO\
dt
the difference between inflow and outflQw, in the direction of
r, is
d (ur^p)
dr
in the direction of 0,
d (rvp sin 0) ^
rdo
in the direction <p,
sin 0 d<p dr dO-
7-^df do dr;
d{re,\n0wp) . , , ,
?• sin 0 d<p d0 dr.
r sin 0d<p
Equating and dividing by d0 dr,
dp . ^ d(ur^p) . ^ , d(rv/>sin^) , d(r Bm0irp) . „
— sm 0=— sm 0^— —sm 0-,
dt r^dr rd0 » r sin. 0d<p
or
dp . d{ur'p) . d(vpBm0) d{wp) . „
— sm 0=— ^sin 0-\— ^ sm 0:
dt r'dr d0 d<p
or if p is constant,
d(Mr') . d{v sin 0) dw . ^ „
— ^sm 0-\— sm ^=0.
r'dr d0 df
Collecting the equations obtained, we have
dp Su J • 2a 2
X rv—r sm 0 w ,
pdr St
Y -f 2 uv—r sin 0 cos 0 w',
pr df, St
Z =r sin —+ 2 sin 0 uw-\-2 r cos 0 vtv,
pr sin 0d<p St
d{ur') . di^vB\\\0) dw .
— ^sm 0-\— 1 sm 0=Q.
r'dr d0 d<p
8 Colorado College Studies.
Equations of a Viscous Liquid.
Cylindrical Co-ordinates.—In treating the equations for
cylindrical and spherical co-ordinates, it is found that the total
rate of displacement, as, for example, on the face CK (Fig. 8)
(Jill
along the normal, is not expressed by —, for if the velocity u
dr
11
is constant there must be an inflow equivalent to —. Conse-
r
quently, in the following treatment account is taken of this,
and then the element considered as uniform in size, ?. e.,
rdO dz is a constant so long as we are considering the ac¬
celeration in u along r. We may therefore consider the total
rate of displacement in the direction of r at surface rdo dz as
du^u
dr r
It has been shown in the derivation of the centrifugal force
that the distance BE=^—^, or a velocity^—(See Fig. 10.)
2r r
If TV is a variable the rate of change on surface dr dz=zv.
Therefore the total rate of displacerhent in direction of 6 at
surface dr dz is
^-2v.
rdo
The rate of displacement along z at surface rdo dr is
du
dz
For the direction of 0^
r*— is the linear displacement at surface rdo dr.
Equations of Motion.
But if V is constant, the rate of linear displacement along r
at this surface is „
zv
The total retardation at surface rdO dz is
tJ-^^^ + 2i^rdd dz.
We have seen before that in order that the form of the ele¬
ment may be maintained there must be a rate of displacement
at rdO dz of
XL
This gives a rate of inflow at dr dz of
2 u
which, added to the rate of inflow due to change of velocity
of rv along rdd, gives a total rate of
dv 2 «
do r
In the direction of 2 the rate is
dv
dz
The rates for the direction of z are the same as in rectangular
co-ordinates.
Collecting these results, we have the following rates of
displacement:
dxL . XL
a.
(1)
(2)
--f-— normal to d2,
dr r
dxi
rdd
■ 2v normal to dr dz,
du
(3) — normal to rdO dr.
dz
(i'V
(1) r ^2v normal to rdd dz,
dr
h. ^ (2)
—-f— normal to dr dz,
dd r
fit)
(3) r— normal to rdO dr.
dz
10
Colorado College Studies.
fn) normal to rd6 dz,
\ dr
c. (2) normal to dr dz,
rdO
(8) normal io rdO dr.
dz
All of the above surfaces, except c (1), are to be considered
constant for the rates have been reduced to those of a uni¬
form element. In the case of c (1), if w is constant there is
no loss within the element, but if w varies along r the total
loss is increased by the increasing area of the opposite face.
Finding the difference in displacement of opposite sides and
multiplying by fi we get,
If these expressions are subtracted from the effective
forces in the corresponding equations for a perfect liquid the
resulting equations are
Equations of Motion.
11
1 (Fn
2 dv J
1
rd0'
rd0
dzV
/ t/ 1 1
pdr St p\dr^ rdr
, o p-l d^'v , 3(7?; , d''v 2du , d'v\
+ 2 nv r 1 ^ 1 \-r—),
p \ dr'^ dr rdO^ i^dO dz'j
prdd St
^ dp _ Sw p./d'w I dw , (fw , d^ti:
Z ———-
pdz St p\dr^ rdr r'^dO- dz^
The cause that contributes —rv' also contributes the rate
of displacement —2?; normal to r sin 0 d<p dr if rv is a vari¬
able. Similarly there are rates, —2 sin(??(; normal to rdo dr
and —2 cosOw normal to rdO dr corresponding to — r sin'^Ow
and —r sin 0 cos Ow' respectively. The first forms a part of
the rate of displacement of u along r sin 0d<p and the second
a part of the displacement of v in the same direction. In
taking account of the acceleration of u along r and of v along
0, it must be remembered that if everything is constant there
is an inflow equivalent to a rate of displacement of — at
r
surface sin 0d'p d0 in the first case and of cot^?; at surface
r sin 0d(p dr in the second case. To the rate of change in v
along r and of v along 0, 2v and —respectively must be added
r
as in cylindrical co-ordinates. If w is constant along r, 0 and
<P, as in the foregoing cases, the rates of displacement at
2u
the initial surfaces are 2 sin2 cosmic, and 1-2 cot0v re¬
spectively. ^
Grouping the rates of displacement, we have
dii 2?
dr r
du
rd§
(1) —-f— normal to ?'■'sin (7^,
(2) -^^—2v normal to r sin0d<p d0,
(3) —^ 2 sin 0w normal to rd0 dr,
r sin 0d<p
_ dv
dr
(Iv
(4) ? ^+2?; normal to r' sin 0d^ d0,
12 Colorado College Studies.
(5) —+ —+ v cot 0 normal to r sin Odf dr,
dd r
civ
(6) ———2 cos Ow normal to rdo dr,
sin Od<p
(7) r sin — +2 sin 0w normal to sin Od<p dO,
dr
(8) sin ^-^ + 2 cos Ow normal to r sin 0d<p dr,
do
(9) —+ —+ 2cot^n normal to d?'.
d<p r
Among the expressions above, (2), (4) and (7) are simi¬
lar to c (1), page 10, in that the losses within the element are
affected by the increase of the opposite faces in one dimension.
In the case of (2) the changing dimension to be considered
is rsinOdf, of (4), r sin Od(p-, and of (7), rdO. Taking this
into account, we obtain the following expressions for the losses
within the element:
.... !>.f(Vu 2du 2jA 2 . . 7 la ]
(1) - — + ^ ) r' sin Od<p do dr,
p\dr^ r r J
/n\ 1>I dihi , du coi 0 2dv 2v , ,
(2) -( 1 cot 0 r' sin Od<p dO dr,
P \ r'^dO^ r^dO rdO r J
/o\ I'l 2dw\ 5 . ,
—)r^^mOdfdOdr,
p \r sin Odf rd<p J
(4) r' sin Od,p dO dr,
p \ dr' dr r /
(5) — -4 —+ cot^ ]r^ Od<p do dr,
p\rdO^ r'dO rdO rsiu'^y
t'l dhi 2 cos Odw\ , . „, ,
(6) : jr' sin Od^ do. dr,
p \r sin 0''d<p'^ r sin Odo J
in\ >'■( ■ <A ■ „die „sin <?7r\ 2 . ,.7
(7) —(r sin 0 1-4sin 0 \-2 ) r sin Od<p dO dr,
P \ dr' dr r J
/ox ,«/sin Sd'w , S cos Odw 2 sin (9?r\ , . ,
(8) h ]r'sin^d^f d(? dr,
P\ rdo' rdo r j
/ox . 2 du ,2 cot Odv\ 2 . „ , -
(9) -[ 1 1 : )?•' sin Od<p do dr.
p\r sin Odf' r' sin Od<p r sin Od<f /
Equations of Motion.
13
Finally we get by annexing these quantities to the corre¬
sponding equations for a perfect liquid:
dp Su , • 2 fd^u , 2u . d^u
X — = vr—rsva.^0uf—v\
pdr SI
du 2dv 2v
cot^ : cot^'-f
di^ rdr r' i^do'
cFh 2 dw\
r'do
dp
rdd
?•" sin ^0 d<p' rd<p
Sv
( dh
— v[ 1—
\ dr
d'o ^ 4:dv . 2v
cPv
dr r
2 cos Odw'
r \-2 uv—r sin 6 cosOw''
crdO St
d'v , 2du dv , „ V
1 1 cot 0 — ^ 4
rd0^ r'd0 rd0 rsin'<' r s\r). ''0d<p' r sin 0d<f
— =rsin^ —4-2 sin^i«c4-2 r cos0 vw—
f'V sin 0d<p St
v si
. „d'w , . . „dw , 2sin(?t« , . „ if w
sin 0 f-4 sm 0 1 h sin 0-
dr^ dr r rd0-
3 cos 0
dw 2 w sin 0
(Pw
2 du
rd0
2 cot 0dv\
r sin 0d<p'' j'^'sin 0d(p r sin 0d<p,
Note I.
For convenient reference the various equations are col¬
lected from the different parts of the foregoing paper; and a
tabulated analysis of the terms appearing in the equations
is annexed. Special attention is given to the terms in the
equations referred to cylindrical and polar co-ordinates.
Su
l>dx St'
&
^ J F—
1 I pdy St'
"s" i ^ dp _Sw
an
co
<
z
t—4
Q
«
o
I
o
O
■<
P
o
s?
c
u
pc3
{ X-
L pdz St
^ I
2 "
o
CO
pdx
dp
St
St)
. f
pdy St
pdz St
UP 11
d'li
dz'J
\ dx^
dy'
'd'v
d'v
1
^dx'
df .
dz'f
./d'w
1 d'w
d'tv'
dy'
dz\
Viscons Liquid.
Perfect Liquid.
N
to
Si.
.-V
•*>
S
C3
CD
-d
CO
+
S"
5"
CD
a.
+
P*
-i
03
5"
C
a
Si
.
<35
s"
Si.
to
-s.
+
5*
CO
5'
<a.
Si¬
's
to "T
+
CO
p
to
o
o
O)
5*
to
o
o
CO
•i
P-
to ^
<2 ^
. a-
I
I
to
+
to
C2
^ I
o I
<rt-
CD
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<5^
a.
•(5
CD
O
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CD
rO
?5
|-S
CJ--* I
n>
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to
to
o
o
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cs
CD
p'
lO
Si.
-s
R-
-s
s^
S:~
to
5
Si. la-
-i I «
+
Vs
Si.
+
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5"
Si.
-s
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P
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to
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Sr
to
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Ki
Viscous Liquid. Perfect Liquid.
, ^ ^ ' —
tSi N ><J tS3 }>-
S
I's
-5
M
"5"
<5 rs
a-
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to
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cc
Equations of Motion. 15
Equations of Continuity for a Liquid.
Kectangular co-ordinates, —+— + — =0,
dx dy dz
Cylindrical co-ordinates, ^ -fu——=0,
dr do dz
•D 1 T 1 d{u7-') . „ , d{vsmO) dw . ^ _
roiar co-ordinates, ^ sin d-\— H sin ^=0.
Cdr do d<p
An Analysis of the Equations.
Rectangular Co-ordinates—The terms found in the equa¬
tions, when referred to rectangular co-ordinates, need but
little explanation. The terms and are due to
dx^ dtf dz'
the variation in the velocity of u in the direction of x, y and
z respectively. And the terms found in the other equations
are due to a similar variation of v and iv.
Cylindrical Co-ordinates—Equations for a viscous liquid.
A"—axis:
— rv' results from centrifugal force due to v,
d'u » du
— results trom —,
dr' dr
— — results from displacement - (see page 8),
rdr r' r
d'u ,, „ d n
results from —,
rW do'
2 dv results from same cause that produces centri-
rdo fugal force —rv' (see page 8),
d'u
— results trom —.
dz' dz
F—axis:
2 uv results from the combined action of u and v,
* (see page 8 and note,)
d'v , dv „ do
r 1 results trom r—,
dr' dr dr
^ results from linear displacement 2i; along r,
dr ■ (see page 9),
16
Colorado College Studies.
tfv - dv
results trom —,
rdo' do
results from - (see page 9),
r^dO r
rd^v 1, » dv
results from —.
dz' dz
Z—axis:
The equation for the forces acting along z is exactly like
that for rectangular co-ordinates.
Spherical Co-ordinates :
X— axis:
—vV results from centrifugal force due to v,
—rsin^Ow^ results from centrifugal force duetoia,
d'u 1, » du
— results trom —,
dr^ dr
2du 2« ,, , 2m . „ , .
^ results from — intiow (see page 11),
rdr r^ r
Aji- cot 0 results from (see page 11).
r'do' r'dO rde^ ^ ^
2 dv 2 ^ results from same cause that produces
rdo r centrifugalforce—ru'', (see also 11,12).
d^u . du
results trom-
r' sin 'Odd' dy
_ 2 dw results from same cause that produces
rd<p centrifugal force —r sin '0 w'.
F—axis:
2 uv results from combined action of u and v,
—r sin 0 cos 0 uf results from centrifugal force due to w,
r—+2— results from r— (see pages 11,12),
dr' dr dr
results from (see pp. 9, 11, 12).
dr r
d'v li i!'
results trom —,
rdo' ■ do
Equations of Motion.
n
results from—(see page 9).
rdd r
cot f>— H—results from r coid (see page 11),
rdf) r sin '^0
d'w dv
results from
r sin -Od<p^ sin Od<p
2 cos 0 dw results from same cause that produces
r sin Od(p centrifugal force —r sin 0 cos 0
Z—axis:
2 sin 0 wii results from combined action of
u and to, (see page 11.)
2 r cos 6 vio results from combined action of
V and to, (see page 11.)
r sin 0 + 2 sin 0 results from r sin 6
dr' dr dr
2 ,i„, + results from 2 sin » «■,
dr
r
. . d^u) . . dw ,, p . ^ dw
sin 0 \- cos 0 results from sin 0—,
rd0'^ rd0 d0
2 cos 0^^ — sin 0 results from 2 r cos 0 to,
rd0 r
d'^io ,, „ dw
results trom
r sin 0d<p- d<f
2 du
r' sin 0d<p
2 cot 0 dv
r sin 0 d<f
results from 2 sin 0 ton,
results from 2 cos 0 v (see p. 12).
Note II.
Advantages of the preceding method of derivation.
The method of deriving the equations of a viscous liquid
which has been received most favorably is that of Stokes.
Both Lamb and Basset have used his method, the first in part
and the second entirely, in their works on Hydrodynamics.
But Stokes' method is based upon two hypotheses. (See
introduction.) The second hypothesis has not been received
18
Colorado College Studies.
very favorably because it involves the assumption that the
motion is slow.
The method which I have used is based upon the defini¬
tion of the coefficient of viscosity and involves no hypothesis
save that of continuity of motion, which has been long re¬
ceived without question.
The derivation of the equations is much simpler than by
former methods, unless an exception is made of the method
of O. E. Meyer, The equations of Meyer are based upon an
assumption which does not satisfactorily explain parts of the
terms. (See introduction.)
The development of the equations of motion by analysis
for cylindrical and spherical coordinates enables us to give a
definite meaning to each term in the equations, and may aid
materially in solving them.
The method definitely determines when the equations
hold and when they do not, as is shown in Note III.
The principal feature of this paper is the relation estab¬
lished between the motion of a perfect and a viscous liquid.
Note III.
The first approximation made in this paper is found on
pages 46 and 47, Colo. Col. Studies, Vol. 7, where all terms
but the first are neglected in the expression.
1 /du did , did did , , \
— 1 l-etc. . . .
dl\ II. id id id /
This approximation is admissable unless the acceleration in
the velocity is very great, which is not usually the case.
In the second place, we suppose the rate of infiow over
the face in a direction perpendicular to the velocity consid¬
ered uniform along the normal to the face. It is easy to
conceive that the inflow might be accelerated. But if it were
the acceleration neglected would be of the second order, and
might reasonably be neglected.
If our conclusions are true, the equations hold not only
when the motion is slow, but in all cases, except when the
motion is rapidly accelerated.
Equations of Motion.
19
Note IV.
On the motion of a fluid in which a circular cylinder of in¬
finite length is slowly rotating.
Whatever motion takes place in the fluid is due to internal
friction, and is two dimensional, i. e., in the plane perpendic¬
ular to the axis of the cylinder.
Let the very natural supposition be made that the layer
of fluid contiguous with the surface of the cylinder moves
with the surface, then the concentric layers will have a motion
due to friction. There will be no motion parallel to the axis,
consequently tc=0; the only force acting along r is that due
to centrifugal force, but since the velocity of rotation is small
the products and squares of velocities may without sensible
error be neglected, consequently u also is equal to 0. There¬
fore to completely determine the motion of the fluid we need
consider only the second of the equations for cylindrical co¬
ordinates.
Since the initial condition was one of rest, the conditions
of equilibrium demand that
5r ii-l d'r , ,/fc , dh'\
—=- r ho 1 1.
of f>\ rdoy
disappearing, since u=0.
disappearing, since this motion is two dimentional.
Since the angular velocity of rotation is small, squares and
products of the velocities may be omitted, hence — becomes
'U
after the rotation has continued long enough for the mo-
dt
tion of the fluid to become steady, —=0, This last is on the
dt
supposition that the velocity of rotation is not accelerated;
and since the motion is symmetrical to the axis of the cylin-
(T^ V
der, becomes 0. The final form for the motion, where
rdo'
20 Colorado College Studies.
angular velocity is constant, is
„ d'c „(/c
0=r ho—.
dd dr
Solving 7'v=kr+ —
r
At an infinite distance ru is insensible, consequently
/v-=0,
c
rv=-,
r
I c
av = —,
a
c=(dv\
fdd
r
But if we consider the cylinder as filled with liquid and con¬
sider the motion of this inclosed liquid,
c=0,
av^=ka,
k = 7-\
where is angular velocity of cylinder. Hence the inclosed
fluid moves as a solid body.—(See Basset, p. 282, Vol. 2.)
Colorado Collec^e Studies. Volume VIII, Plate II.
Colorado College Studies.
Volume VIII, Plate I.
THE CAPRICORNS, MAMMALS OF AN ASIATIC
TYPE, FORMER INHABITANTS OF
THE PIKE'S PEAK REGION.
[X popular lecture delivered before the Colorado College Scientific Society on the
:i7th of October, I8fl9, and here reprinted with some revision from tlie Colorado
Springs Gazette of November 12th, 1899.]
By F. W. Cragin.
As most of my audience are aware, the granite of the Rocky
Mountains, though commonly building our highest peaks, has
been raised to such elevated positions from an origin deep
down in the earth's crust beneath the stratified rocks.
These latter members of the earth-crust have been depos¬
ited almost wholly by water, largely oceanic, in small part
fresh, as mechanical, chemical and organic sediments, long
since consolidated into rock, that covered the granite like a
series of thick, more or less nearly horizontal blankets.
The upward movement is attested by a thousand basset
edges of strata, of which the Gateway of the Garden of the
Gods and the hog-backs north and south of Colorado City are
conspicuous examples, upturned by the ascending portion of
the granite, and which still are seen, though profoundly cut
down and reduced to the merest remnants, the mountain-
blanket having been almost wholly cut away in the case of
Pike's Peak itself, by erosion.
The granite and its burden of stratified rocks were thrown
into mountain folds in the region of the Rockies chiefly at
the close of the Cretaceous age, the last of the three ages of
the great Mesozoic era; which means that, for the most part,
the Rocky Mountains were born at the end of the ocean's
sway over interior North America, though that sway, prior to
that time, had tiot been uninterrupted, for the Pike's Peak
region stood above the sea during parts of at least three earlier
geological ages — the Devonian, the Carboniferous and the
Jurassic — and probably during parts, also, of others, as is
witnessed by the absence from it of Devonian rocks (sedi¬
ments), the presence near Manitou of thick Carboniferous
22 Colorado College Studies.
•
beach-deposits, and the fact that the Jurassic is represented
here solely by a great fresh-water lake deposit in whose
border-muds, near Canon City, Colorado City and Morrison
and elsewhere, bones of huge walking reptiles, the Dinosaurs,
including some, like Atlantosaurus and its allies, eighty or
perhaps even one hundred feet long, the most ponderous land
animals known ever to have trod the earth, have lain stranded
to the present day.
Of all the stratified rock-systems represented at the east¬
ern base of our front-range, the Manitou limestone, of Silurian
age, is nearly the oldest, only one, the underlying formation
of red sandstone, gravel and lime, which, from its deep-green
glauconitic variegations and its typical occurrence about
Rainbow Falls, may well be called the Rainbow formation,
belonging to an earlier age, the Cambrian. The extensive
system of caves found in the Manitou limestone, and of which
the Pickett cave, or Cave of the Winds, and the Grand Cav¬
erns, besides several smaller caves, are a part, have been made
primarily by the solvent and secondarily by the transporting
action of carboiiic-acid-laden waters that formerly circulated
through the joints and other fissures of the limestone. Sub¬
sequently, as happens to most caves sooner or later, those of
the Manitou limestone have been to a greater or less extent
filled with a reddish sediment, known as cave-earth, which it
is necessary to remove in order to display the subterranean
galleries and chambers in anything like their original dimen¬
sions. The cave-earth in many instances is barren, or con¬
tains only sparingly the remains of recent animals; but in
others it yields the bones of extinct animals, throwing light
on the history of both the cave and the surrounding region.
In having the cave-earth removed from a cave in this lime¬
stone in Glen Eyrie a few years since. General Palmer saved,
"with his usual foresight, the organic remains, consisting of a
number of bones, thrown out with the earth by the workmen,
and these he very kindly submitted to me for determination.
Two of the specimens were at once recognized as proximal
phalanges of an extinct species of Horse, whose remains occur
abundantly elsewhere with those of Elephants, bulky, armored
Ground-sloths,Llamas as large as Camels, Saber-toothed Tigers
The Capkicobns, Mammals of an Asiatic Type. 23
and other extinct animals of late Pliocene to Pleistocene age.
The other remains found in the cave at Glen Eyrie were iden¬
tified last summer, when I was first able to compare them with
extensive series of skeletons in the United States National
Museum. The smaller bones — a jaw and two femurs—were
soon found to belong to a species of Woodchuck, different
from the common one of eastern North America, and not im¬
probably so from the Yellow-bellied Woodchuck, which is the
present sjiecies of the central Rocky Mountains. The large
bones pertained to the right fore limb of a young ruminant,
or two-toed ungulate, which some ancient beast of prey had
doubtless dragged into the cave as a choice morsel to feed
upon at leisure. They were humerus and cannon-bone
(metacarpus), in which part of the epiphyses were missing,
not yet having united with the shaft. It was at first thought
that they might have pertained to a Rocky Mountain Sheep,
or Big-horn. From the skeleton of this, however, they widely
differed, as they also did from the Mountain Goat of North¬
western America, and from skeleton after skeleton with which
they were compared, until the whole range of modern two-
toed ungulates of North America had been gone over. Then
Asiatic forms were tried, and it was soon found that the bones
closely agreed with those of the Capricorns, or Goat-antelopes,
a genus of animals technically known as Nemorhccdus, and
represented to-day by several siiecies living in the Himalayas
and other mountains of Asia, Japan and Formosa. They be¬
long to the family Bovidae, which includes also the Cattle,
Sheep, Goats and Antelopes. They are intermediate in their
characters between the Goats and Antelopes, whence the
alternative name. Goat-antelopes; they are also sometimes
called Mountain Antelopes. It is interesting to note that
they range at altitudes of 3,000 to 8,000 feet, the cave at Glen
Eyrie being within these limits.
There are tw^ sections of the genus Nemorhozdus. One
includes clumsier built animals, which, however, resemble the
deer in having a tear-pit in the face, and which are solitary in
habit; these are the Serows, of the sub-genus Cupricornis.
The other, of the section or sub-genus Kemas, includes the
graceful forms, the Gorals, which lack tear-pits, and go in
24
Colorado College Studies.
small parties. It is impossible, in the absence of a skull
from the Glen Eyrie material, to be quite sure whether the
particular Capricorn that inhabited the Pike's Peak region
was a Serow or a Goral. Of the Serows, the osteological col¬
lections of the National Museum included ^ skull, but no
skeleton; but the agreement of the two limb-bones with the
corresponding ones of the species of Goral in the museum
{Nemorhcedtis cn'sjius, or Kemas crispiis, of Japan) is such
that the slight differences can hardly be considered of more
than specific value, and it seems probable that our Eocky
Mountain Goat-antelope was a Goral. A glance, therefore,
at the species of Goral that inhabits an interior mountain
region of Asia corresponding with ours of North America
may be of interest. The following account of the Goral of
the Himalaya is derived in part from Jerdon's " Mammals of
India " and in part from Lydekker's " Chapters on Hoofed
Animals."
The animal is very caprine in appearance, the back some¬
what arched, the limbs stout and moderately long. It is well
adapted for both climbing and jumping. It stands some
twenty-seven to thirty inches high at the shoulder, the head
and body measuring fifty, the tail four, and the horns eight
inches in length. The horns, which are present in both
sexes, and only a little larger in the male than in the female,
incline backward and slightly inward, and are a little re¬
curved; they are shorter than the skull, black in color, round
in cross-section, and ornamented with twenty to twenty-five
encircling raised folds. The fur is somewhat rough, of two
kinds of hair, and there is a short, semi-erect mane in the
male. The color is brown, with a more or less decided gray
or ruddy tinge, a little lighter beneath. The throat is white.
A dark line runs down the back from crown to tail, and the
front surfaces of the legs are also marked with dark streaks.
Though found considerably higher and lower, the Himalayan
Gorals are commonest at elevations of 5,000 to 6,000 feet above
sea-level. They inhabit rugged, grassy hills and rocky ground
in the midst of forests, and are usually found in small family
parties of three to eight. If one Goral is seen, you may be
pretty sure that others are not far off. They rarely or never
The Capeicorns, Mammals of an Asiatic Type, 25
forsake their own feeding grounds. In cloudy weather they
feed at all hours of the day; in fair weather, only morning
and evening. When one is alarmed it gives a short hissing
sound, which is answered by all within hearing. Goral stalk¬
ing is with many a favorite sport in the middle ranges of the
Himalaya. The illustration of the Himalayan Goral herewith
given is enlarged from Lydekker's work above cited; for the
use of it here I am indebted to the Colorado Springs Gazette.
Himalayan Goral.
If the range,of the Pike's Peak Capricorn corresponded
nearly with that of the Himalayan, and the cave of the Cap¬
ricorn-eating carnivore was conveniently located within the
zone of greatest abundance of the quarry—5,000 to 6,000 feet
above sea-level—the Rocky Mountain plateau must have stood
something like one or two thousand feet lower in its Capri-
26
CoLOKADO College Studies.
corn epoch than to-day, as the present elevation of the cave
approaches 7,000 feet. And as the two conditions above
predicated are those most likely to have prevailed, it seems
quite probable that Nemorhoedus as an element of the North
American fauna, belonged to the Champlain phase of the
Glacial epoch.
Though the differences may be due to variant conditions
of preservation in the cave-earth in which they were imbedded,
and hence not significant of difference in age, the Horse
phalanges from the cave at Glen Eyrie are darker, heavier,
and much more thoroughly mineralized than the bones of
the Capricorn, and are, seemingly, much older. They belong,
however, to rather a slender-limbed type of Equus that occurs
in Kansas in deposits which are probably late Pliocene or
early Postpliocene, and thus tend to show that the caves in
the Manitou limestone date back at least as far as the begin¬
ning of the Quaternary, and not improbably had their origin
in the later part of the Tertiary age.
The finding of Goat-Antelopes as members of the Pleisto¬
cene or earlier fauna of the Rocky Mountains was quite un¬
expected, but is no more remarkable than that Elephants,
which, not only by present habitat but also by the very place
of their origin from the Mastodon stock, are Asiatic types,
abounded in Pleistocene times throughout North America, to
which the Asiatic fauna doubtless had measurable access by
way of lands now interrupted in the vicinity of Behring's
Straits. The Asiatic Mammoth occurs in transsierran Amer¬
ica, and Elephant remains of an extinct species related to
the Mammoth and to the Modern Asiatic, rather than the
African Elephant, are common on the Great Plains, and not
rare in the old river gravels which underlie Denver, Colorado
Springs and Colorado City, and have been found as high in
the Rocky Mountains at least as the bogs of Grassy Gulch,
in the Cripple Creek district. It serves to show how imper¬
fect still is our knowledge of even the most recent chapters
of the earth's history, to emphasize the interest of the great
stone book of nature which too often we pass by without an
attempt to read, and to show how the darkest cave, carefully
studied, may prove a torch to illumine a page of that book as
well as its own mystic interior.
BUCHICERAS (SPHENODISCUS) BELVIDERENSIS
AND ITS VARIETIES.
By F. W. Cbagin.
SpHENODISCUS BELVIDERENSIS. Crag.
Shell of medium size, flattish-lenticular, the venter (per¬
iphery) truncate, narrowly so on the younger whorls, broadly
and less sharply and less evenly so on the oldest one, particu¬
larly on the body-chamber; body-chamber occupying three-
eighths to one-half of a volution; umbilicus narrow, the greater
part of the height of the second whorl being embraced within
one-third to one-half of that of the body-chamber; suture
"■ ceratitic," much like that of Sphenodiscus pedernalis^ Von
Buch, the part corresponding to the outer saddle of (strictly
so-called) Buchiceras being divided into five saddles by means
of four leaves, of which the very unequal outer two are much
smaller than the subequal inner two; all of the saddles of
the suture rounded to flattish or, in case of some of the inner
ones, emarginate at fundus, some symmetrically, some ob¬
liquely so, and all much broader than the leaves, excepting
the next to the outermost of those formed by the lobing of
the outer buchiceran saddle; the leaves little cleft at the
summit; ornamentation of the shell consisting usually of at
least two revolving series of low tubercles on either side: one
just outside of the umbilical shoulder, and consisting of few
tubercles, one or two of the newer of which sometimes be¬
come more prominent than any other tubercles on the shell;
the other, presented ventrally on the ventro-lateral margin,
and consisting of numerous tubercles so compressed as to
trend with that margin, and so arranged that those of the right
alternate with those of the left margin, half (consisting of
every other one) of these tubercles constituting the termini
of broadly and feebly accentuated lateral ribs, which are con¬
fined to the outer part of the flank, and at whose inner ends
(one at the end of each) the very low and diffuse tubercles
of a third revolving series may be developed.
28
Colorado College Studies.
Measurements.— The shell of this ammonite attains a
height of at least 125 mm.; that of the body-chamber about
half as much.
Occurrence and History.—In Texas this is the common¬
est Sphenodiscus of the Comanche Peak limestone; and in
Kansas it is, so far as the writer has observed, the only rep¬
resentative of its genus in the Champion shell-bed and the
Kiowa shales, being associated there with the common Fred¬
ericksburg and Kiowa ammonite, Schloenbachia peruviana,
Von Buch. All of the truncate Sphenodisci hitherto found
either in the Comanche Peak limestone and Champion shell-
bed, or in later rocks of the Comanche series, are here pro¬
visionally included under this species, though some of the
supposed varieties may prove to be distinct, and some are
doubtless of sti-atigraphic importance.
Messrs. Stanton and Hill have recently* called attention to
the fact that a Sphenodiscus differing from S. pedernalis.
Von Buch, by its truncate venter, occurs in the Belvidere
beds of Southern Kansas.f I had observed the same fact in
1889, as witnessed by figures 1, 2 of Plate I, here reproduced
from rough lead-pencil sketches which I made at that time,
of a Champion shell-bed specimen that I was once inclined
to separate from S. pedernalis and describe as new. I after¬
ward gained the impression that the truncate character of
the periphery was inconstant, and did not signify a species
distinct from S. pedernalis, but only a variety. Hence the
broad use that I have generally made of the name Sphenod¬
iscus pedernalis.
I now agree fully with the above-cited statement of Messrs.
Stanton and Hill, and confirm also my own former supposi¬
tion of the distinctness of these truncate Sphenodisci from
S. pedernalis.
The specific name, helviderei (afterward changed to bel-
viderensis), was first applied to this species in 1890 in my
article "On the Cheyenne Sandstone and the Neocomian
Shalesof Kansas"J 'whexelWsiQd"'AmmonitesBelvidereV as
♦Except the two figures noted as sketched in 1889, the manuscript and drawings
of the preseat article were prepared in the spring of 1897.
t Am. Jour. Sci., Third Series, Vol. L, June, 1895.
t Bui, Washburn Coll. Lab. Nat. Hist., No. 11, March, 1890.
Buchiceras (Sphenodiscus) Belviderensis. 29
occurring in No. 5 of my Blue Cut Mound section (the Ful-
lington horizon of the Kiowa shales). The specimens so
recorded were small ones, of which the drawings were made
in 1889, and published, without comment, in 1894.* They
were assigned a specific name because smaller, plainer and
simpler-sutured than those recorded in 1889 and 1890 as
^'Ammonites pedernalisfrom the Champion shell-bed; f
but the Fullington and Champion forms are now regarded as
belonging to one variable species, which must, therefore, take
the name belviderei, or its modified form, belviderensis.
Of this species there appear to be five varieties that call
for notice. These may be described as follows:
Var. mons-comancheanus.
Plate I, fig. 5.
Suture relatively complex for this species, having even
the smaller leaves more or less cut at the summit, usually
with two or three simple, obtuse lobules, and the larger leaves
cleft into a larger number (4—6) of processes which are
either simple and short (tooth-like) to somewhat longer (sub-
digitiform), or show a tendency to secondary toothing, one
or two of the processes being expanded at the extremity and
abruptly truncated or notched. Of the saddles centripetally
succeeding the five secondary saddles,^ the first three are
simple and subrotund (the first one a little compressed), with
rounded to truncate extremity, the next two (respectively
just outside of and opposite the circum-umbilical tubercles)
are broader than deep and strongly emarginate or bilobate,
being parted into two lobes by a small and short clavate leaflet.
The type is from the Comanche Peak limestone of Tarrant
County, Texas; and to this variety the common Sphenodiscus
of the Champion shell-bed (illustrated in figures 1 and 2 of
Plate I) seems^to belong.
♦New and Little Known Invertebrata from the Neocomian of Kansas. Ameri¬
can Geologist, XIV, Plate I, figs. 3-5. July, 1894.
t Geological Notes on the Region South of the Great Bend of the Arkansas. Rul.
Washb. Coll. Lab. Nat. Hist., No. 9, February, 1889; and, On the Cheyenne Sandstone
and the Neocomian Shales of Kansas. L. C. No. 11.
t The term " secondary saddles " is used as a convenient designation for the five
saddles into which, by foliolation, the external saddle of typical Buchiceras is sub¬
divided in Sphenodiscus.
80
Colorado College Studies.
Var. clavatus.
Plate II, figs. 1-3.
Suture considerably less complex than in similarly sized
specimens of mons-comancheanns, the leaves being capitate-
clavate, the summits of the larger leaves departing less (or
at most, not more) from a simple outline, in a specimen ex¬
ceeding 100 mm. in height, than do those ofthe little (27 mm.)
specimen of Sphenodiscus belviderensis figured in Vol. XIV
of the American Geologist, Plate I, figs. 4, 5. In a smaller
specimen (which, if the missing portion of the body-chamber
were restored, would have a height of about forty-seven or
forty-eight mm.), the first four (all that the specimen shows)
of those saddles that succeed the secondary, are not emarg-
inate, the first and third of them being narrower (the first
narrower than the third), and of rounded outline, the second
and fourth being broader and truncate. The two type speci¬
mens were obtained, with the type of mons-comanclieaniis,
from the Comanche Peak limestone of Tarrant County, Texas.
Var. uddeni.
Plate I, figs. 3 and 4.
Suture relatively complex, the primary lateral and the
larger secondary lateral and auxilliary leaves little different
from those of var. mons-comancheanus, the leaves and saddles
interior to the secondary ones being as follows: First and
second lateral leaves irregularly and obtusely dentate, inclos¬
ing a large, simple, subrotund saddle; these followed in suc¬
cession by a deeply emarginate saddle; an intermediate-sized,
asymmetrical, feebly denticulate leaf; three simple, subro¬
tund, subequal saddles, parted by two small, narrow, simple,
clavate leaves; a small emarginate leaf; a small deeply emargi¬
nate saddle; a narrow emarginate leaf; a broad emarginate
saddle (this in the line of the series of circum-umbilical
tubercles); and finally, a small leaf and saddle, both emargi¬
nate. The type-specimen of this variety is in the museum of
Augustana College, and was kindly loaned me for study by
Prof. J. A. Udden, who collected it in the Kiowa shale, a
few miles west of Lindsborg, Kansas, and for whom it is
named.
Buchiceras (Sphenodiscus) Belviderensis. 31
Var. MENTORIANUS.
Plate I, figs. 6 and 7.
This variety is distinguished by having the two simple,
truncate saddles second and third exterior to that which is
in the course of the circum-utnbilical tubercles, remarkably
broad and shallow. The type is from the Mentor beds, near
Brookville, Kansas.
Var. SERPENTINES.
Plate II, figs. 4-6. -
Venter of entire body-chamber strongly and rather nar¬
rowly rounded and sinuous, the convexities of the sinuosity
being correlated with pronounced, rounded or somewhat sud¬
denly flattish-crested ribs on the outer part of the body-
chamber, the tubercles seen on the ventro-lateral margin of
typical belviderensis being nearly lost in the ventro-lateral
shoulders of tlie ribs; the ribs separated by broadly round-
bottomed valleys of about their own breadth, and disappear¬
ing about midway between the venter and the umbilicus; a
series of obliquely compressed tubercles encircling the um¬
bilicus. Of the septate portion of the shell, only the anterior
part has well-developed ribs and tubercles, and a distinctly
sinuous and rounded venter, the posterior part of the venter
being abruptly truncate, as in typical belviderensis.
This sub-species is common in and characteristic of the
Denison division, though its occasional occurrence in the
Washita division also is probable. The types are from the
Pawpaw clays near Denison.
THE NUMBER CONCEPT.
by florian cajori.
For the benefit of teachers who do not have access to a
modern mathematical library it is proposed in this compila¬
tion to present the views of mathematicians of the present
time relating to number, its origin and nature. We shall
begin by giving what is considered to be the pi-imary num¬
ber concept; then we shall briefiy indicate how the original
and primitive idea of number is extended so as to apply to
measurement.
Pbimaky Number.
" Separateness or distinctness is a primary cognition, being neces¬
sary even to the cognition of things as individuals, as distinct from
other things. The notion of number is based immediately on this
primary cognition.
" Number is that property of a group of distinct things which remains
unchanged during any change to which the group may be subjected
which does not destroy the distinctness of the individual things. Such
changes are changes of the characteristics of the individual things or
of their arrangement; for these do not cause one thing to split up into
more than one, nor more than one to merge in one The
number of things in any two groups of distinct things is the same, when
for each thing in the first group there is one in the second, and recipro¬
cally, for each thing in the second group, one in the first.
"Thus, the number of letters in the two groups. A, B, C; D, E, F,
is the same. In the second group there is a letter which may be assigned
to each of the letters in the first: as D to A, E to B, F to C: and recip¬
rocally, a letter in the first which may be assigned to each in the second;
as A to D, B to E, C to F.
" Two groups thus related are said to be in one-to-one (1—1) corre¬
spondence The fundamental operation of arithmetic is
counting. To count a group is to set up a one-to-one correspondence
between the individuals of this group and the individuals of some rep¬
resentative group. Counting leads to an expression for the number of
things in any group in terms of the representative group: if the repre¬
sentative group be the fingers, to a group of fingers; if marks, to a group
of marks; if the numeral words, or symbols in common use, to one of
these words or symbols."—Prop. H. B. Fine, of Princeton, in The Num¬
ber-System of Algebra. 1891, pp. 3, 4, 5.
The Number Concept.
33
" To count things means to consider them as alike, to take them
together, and to associate with them, singly, other things which are
also considered alike. Each of the things with which other things are
associated in counting is called a unit; each of the things which in
counting are associated with other things is called a one. The result of
counting is called number. On account of the likeness (Gleichartigkeit)
of the units among themselves and of the ones among themselves, the
number is independent of the order in which the ones are associated
with the units.
"If in a number we specify to what extent the units were consid¬
ered as being alike, by assigning a collective name to the units, then we
have a concrete number. By completely ignoring the nature of the
things counted we pass from the notion of a concrete number to the
notion of an abstract number.
"By the word number, unqualified, we shall always understand an
abstract number."—Bubkhardt and Meyer's Encyklopadie der Mathe-
matischen Wissenscliaften. Part I, Vol. I, 1898, pp. 1-3.
"To count distinct things means to make of them an artificial indi¬
vidual or group, and then to identify its elements with those of a familiar
group."—Prof. G. B. Halsted, in Science. N. S., Vol. VIII, 1898,
p. 909.
" Counting presupposes the comparison of multitudes (Vielheiten).
By multitudes we mean a group of objects alike among themselves;
that is, we convey the notion of disjunctive things, the differences of
which remain unnoticed, and the mode of arrangement of which is
disregarded. Two multitudes are called equal when with each object
of the first there is associated, singly, one of the second and none remain
disassociated. Th*t multitude is called greater than another which has
some objects left disassociated after every object of the second (smaller)
multitude is associated singly with some object of the first. The com¬
mon mark (Merkmal) of all multitudes which are equal to a definite one
is expressed by a numeral word The natural number is a
multitude of units, that is of ones."—Otto Stolz, of the University of
Innsbruck, in Vorlesungen uber Allgemeine Aritlimelik. 1885, pp. 9,10.
84
CoLOBADO College Studies.
" In fine, we live. We are surrounded by objects; the idea of com¬
paring these objects, to consider the groups which they form with each
other, is natural to man, and has, we are sure, presented itself to him
since early times. Attentive observation reveals to us the fact that
objects do not exist exactly equal to one another; but, through an opera¬
tion of the mind which demands no effort, although it involves the
entire secret of mathematical abstraction, we consider as alike the
bodies which seem to us to resemble each other, and we wave momen¬
tarily the examination of the differences which distinguish the one from
the other. Hence arises the origin of calculation; the process of count¬
ing is in general quite simple, even to those who are the least mathe¬
matical. Thus, if we count the trees in a park, we know full well that
the trees may be of different kind, that they are not the same in shape,
that they have not the same age, nor the same number of branches and
leaves. Some grains of wheat are placed on a table; we say, here are
twenty-five grains of wheat, and if we set ourselves to examine them
with a magnifying glass, we perceive that each has its special proper¬
ties which enable us, if necessary, to distinguish it from all the rest.
But by a conventionality that is natural and even instinctive, we have
created in the term " tree " or " grain of wheat " an abstraction which
is indispensable in the act of counting."—C. A. Laisant, La MatMmat-
iqiie, Philosophie-Enseignement. Paris, 1898, pp. 15-16.
" Primary number is an abstraction from a group of objects which
represents their individual oxiBtcncc."—A. Lefevre, Number and Its
Algebra. 1896, p. 20.
"The word which stands at the head of this chaper [ " number " ]
contains six letters. In order to find out that there are six, we count
them; n one, u two, m three, b four, e five, r six. In this process we
have taken the letters one by one, and have put beside them six words
which are the first six out of a series of words that we always carry
about with us, the names of numbers. After putting these six words
one to each of the letters of the word number, we found that the last
of the words was six; and accordingly we called that set of letters by
the name six.
" If we counted the letters in the word ' chapter ' in the same way,
we should find that the last of the numeral words thus used would be
seven; and, accordingly, we say that there are seven letters. But now
The Number Concept.
35
a question arises. Let us suppose that the letters of the word number
are printed upon separate small pieces of wood belonging to a box of
letters; that we put these into a bag and shake them up and bring
them out, putting them down in any other order, and then count them
again ; we shall still find that there are six of them. For example, if
they come out in the alphabetical order, 6, e, m, n, r, u, and we put to
each of these one of the names of numbers that we have before used,
we shall still find that the last name will be six. In the assertion that
any group of things consists of six things, it is implied that the word
six will be the last of the ordinal words used, in whatever order we take
up this group of things to count them. That is to say, the number of
any set of things is the same in whatever order we count them.
"Upon this fact, which we have observed with regard to the particular
number six, and which is true of all numbers whatever, the whole of
the science of number is based."—W. K. Clifford, Common Sense of
the Exact Sciences. 1891, pp. 1, 2.
" The oldest calculations were probably achieved by a certain ar¬
rangement, either of the objects themselves, which were the subject of
calculation, or of other things more easily handled. Pebbles, small
shells, may have served as representatives, as they still do at the pres¬
ent time among certain tribes, and these marks . . . , when brought
into smaller or larger heaps, arranged in rows, will have facilitated
materially the adding together or the division of a collection of objects.
As long as only small numbers had to be dealt with, man carried the
simplest mode of visualization with him; namely, the fingers of his
hands and the toes of his feet. To be sure, he could not thereby advance
very far without some new device. Certain tribes of South Africa still
show us to-day how friendly cooperation may be used to overcome the
difficulty of visualizing larger numbers by using the fingers only. ' In
counting beyond one hundred the difficult task must, as a rule, be per¬
formed by three men. One of them counts the units on his fingers, by
raising one finger after the other and pointing out the object counted
or, if possible, touching it. The second man raises a finger (always
beginning with the little finger of the left hand and proceeding continu¬
ously toward the little finger of the right hand) for every ten, as soon as
it is completed. (Jhe third man counts the hundreds.' *
" Whatever explanation may be offered for the fixed order of using
the fingers, the fact of its existence remains, and in the course of our
researches we shall repeatedly encounter this fixed order as the founda¬
tion of the so-called finger counting.'"—M. Cantor, of Heidelberg, in
Vorlesungen uber Geschichte der Mathematik. Vol. I, p. 6. 1894.
*ScHKUMPF, in Zeitschrift d. deutsch. morgenldnd. Gesellschcfl XVI, 463.
30
Colorado College Studies.
"But men did not arrive at this use of the fingers till they had
already made some little progress in calculation without them. That
this is the true history of the art of counting is evident, if we consider
the following facts in order:
" First, there is hardly any language in the world in which the first
three or four numerals bear, on the face of them, any reference to the
fingers. Secondly, there are many savage languages in which these
numerals are obviously taken (not from the fingers, but) from small
symmetrical groups of common objects. Thus, ' two' is, among the
Chinese, ny and ceul, which also mean ' ears'; in Thibet, paksha,
' wing'; in Hottentot, VKoam, ' hand '; and so, also, among the Java¬
nese, Samoyeds, Sioux and other peoples. So, again, with the Abipones,
\
' four ' is geyenknati,' ostrich toes ':' five' is neenhalek, ' a hide spotted
with five colours '; with the Marquesans 'four' is pona, a ' bunch of
four fruits,' etc. Thirdly, there are also many savages who, having
only a very few low numerals, count to much higher numbers dumbly
by means of the fingers.
" But just as, in the examples quoted above, the name of the pattern
group (e. g. ears or hands) becomes the name of the number which that
group contains, so with finger-counting, the savage, advancing in intel¬
ligence, begins to name the gesture with or without performing it, and
this name becomes the symbol of the number which the gesture is meant
to indicate. Hence, all the world over, in nearly every language under
the sun where names for the higher units exist and show a clear
etymology, the word for 'five' means 'hand,' and the other numbers,
up to ten or twenty, as the case may be, are merely descriptive of finger-
and-toe-counting."—J. Gow, History of Greek Mathematics. 1884,
pp. 6 and 7.
Bemarks.
(1) From the above citations, copied from representative
books of our time, it appears that the mathematicians of the
present day are unanimous in describing the earliest notions
of number as being free from ratio and measurement. It is
worthy of notice, moreover, that the great historians of mathe¬
matics are led from archaeological and ethnological study to
results in agreement with those of the mathematicians.
(2) The only data which must be supplied to the mind
through the senses for the cognition of number are the sepa-
rateness or distinctness of objects. For the earliest cogni-
The Number Concept.
37
tion of number, it is necessary and suflBcient to see, hear or
feel things as differentiated one from the other. The child
may, at the same time, be conscious of form, of the fact that
one body is larger or smaller than another, but form and size
are not necessary for the primitive number-concept.
(3.) Counting is the simplest mathematical act. Yoi-meas¬
uring, the senses must supply to the mind more data than are
needed in counting, and the data must be more accurate.
For counting, the child only needs to see one object as sepa¬
rate from another; for measuring, he must also see one as
greater than another. Take two rods, one twice as long as
the other. For measurement, the child must not only see
them as distinct rods of unequal length, but he must apply
the smaller rod to the larger, either in imagination or by
actual manipulation. The fact that the smaller rod can be
mai'ked off twice on the larger conveys no idea of ratio, unless
the child has, beforehand, the primitive number-idea. If
this idea is present, then he may recognize the parts of the
longer rod as " two," and may obtain the idea of ratio. But
if the child has not the number-concept for " two," then it
seems impossible for him to acquire an idea of the ratio be¬
tween the lengths of the rods. The child must know that
the length of one rod is some number of times the length of
the other, before he can find out how many. If the primary
concept of number is a prerequisite to any attempt at meas¬
urement, then one cannot find the origin of number in
measurement.
Extension of the Number-Concept. (Katio, Fractions.)
" The first extension of the concept of number is the identification
of the ratio of any two magnitudes of the same kind, and without quali¬
tative distinction for the purposes of the comparison, as a number."
"The measurement of any magnitude (concrete or abstract) is the
process of finding its ratio to another magnitude of the same kind, arbi¬
trarily chosen as a unit. The measure of a magnitude is this ratio — a
number."—A. Lefevke, Number and Its Algebra. 1896, pp. 61, 125.
38
CoLOKADO College Studies.
"Measuring in the ordinary sense — the process which leads to the
representation of continuous magnitudes as lines or surfaces, in terms
of some unit of measure — deserves all the prominence which our au¬
thors [McLellan and Dewey] would give it in arithmetic. We do not
mean measuring in the exact mathematical sense, of course, but the
rough measuring of common life, in which the magnitude measured and
the unit are always assumed to be commensurable. Compared with
counting, or even addition and multiplication, an operation which in¬
volves the use of an arbitrary unit, and the comparison of magnitudes
by its aid, is artificial. But this metrical use of number is of immense
practical importance, and of great interest to any child mature enough
to understand it. No doubt a child may use a twelve-inch rule to ad¬
vantage when practicing multiplication and division of integers. Cer¬
tainly, such an aid is almost indispensable in learning fractions. Without
it, the fraction is more likely to be a mere symbol to him, without exact
meaning of any kind. ' Two-thirds ' has a reality for the child who can
interpret it as the measure of a line two inches long in terms of a unit
three inches long, which it quite lacks for him who can only repeat that
it is 'two times the third part of unity.' Mathematicians now define
the fraction as the symbolic result of a division which cannot be actually
effected, but that definition will not serve the purposes of elementary
instruction. It is as certain that the fraction had a metrical origin as
it is that the integer had not, and in learning fractions, as in learning
integers, the child cannot do better than follow the experience of the
race."—Prof. H. B. Fine, in Science. N. S. Vol. Ill, 1896, p. 136.
The most ancient mathematical hand-book known to our
time—the Ahmes papyrus, about 2000 B. C., which claims to
be founded on much older Egyptian documents—begins with
fractions. It was probably written for the advanced mathe¬
maticians of its day. The study of this document shows how
difficult fractions were to the ancients. Ahmes confines him¬
self to unit-fraclions having unity for their numerators.
If another fractional value was to be considered, it was al¬
ways expressed as the sum of two or more unit-fractions.
Thus; A=ih+iV. And how did the necessity of the in¬
troduction of fractions arise? The document contains prob¬
lems like this, " Divide 2 by 3," and Ahmes solves this by
means of his fractions. Thus dividing 5 by 21 gives V ih ih.
That the idea of measurement was predominant in the use
of these fractions follows from such problems in Ahmes as
The Number Concept.
39
the computation of the average daily pi'oduce of fat, when
the yearly produce is ten "besha," and from the geometrical
examples dealing with areas of land. For instance, a trian¬
gular piece of land is computed as having half the area of
the corresponding parallelogram.
Apparently, number first suggests itself to the child in
connection with discrete things. He sees three distinct ob¬
jects, and learns to count one, tico, three. In measurement
(of lengths, for instance) the mind marks off some unit of
length (the foot) along the length to be measured (a yard¬
stick, let us suppose), and thereby comes to imagine the
yard as made up of parts; the measured length is thought of
as composed of three equal parts; that is, by a mental act the
continuous length is pictured as made up of discrete parts of
a group of like objects. The original or primitive yard-stick
is differentiated by the mind into an artificial group of three
equal lengths. A pencil is found to be six inches long; the
mind at once pictures a group of six equal lengths, which
have become discrete objects of thought. In the counting of
separate objects, we, by a process of abstraction, consider the
objects as alike; in measuring, by a further mental process,
we consider a continuous magnitude as made up of separate
like parts.*
In measurement we extend the number concept so that it
is applicable not only to things that are discrete or discon¬
tinuous, but also to things which are continuous. We can
now say that ratio is a number, but we are not allowed to say
that number is always ratio. Number in general is a broader
term than ratio.
While in the crude measurements of every day life all
magnitudes appear to us as commensurable with one another,
mathematical reasoning shows that incommensurability may
exist. The keen intellect of the Greeks first detected the
fact that the si(^e of a square and its diagonal are incommen¬
surable with each other. Hence in the refined reasoning of
the mathematician it is not sufficient for measurement to
deal with ratios which are integers or ordinary fractions, but
with numbers which are incommensurable to the measuring
♦ Consult an article by Prof. G. B. Halsted, in Science, N. S.,Vol. Ill, pp. 470,
471, to which I am indebted. See also Ceifford, loc. cit., p. 95.
40
Colorado College Studies.
unit. Thus, the connotation of ratio (embracing both the
rational and irrational) as number enables us to make num¬
ber continuous, so that, starting with a ratio as small as we
please, we can conceive number to increase continuously,
passing through all the stages of primary number and all
the interspersed stages of irrational number, to a ratio as
large as we please.
But the notion of continuity is not as simple as it, at first,
appeal's to be. Few notions in mathematics are more subtle.
It is in considerations of this sort that the logical superiority
of the reasoning based on numbers is asserting itself. In
advanced mathematical research, the greatest rigor of treat¬
ment is secured, not by relying on intuition, not by depend¬
ing on geometrical figures, but by an entire separation from
the world of our senses, and making mathematical demon¬
strations wholly arithmetical. Through reliance on their in¬
tuitions, mathematicians have been led to some erroneous
results; for instance, that every continuous function must
have a derivative at all points in a given interval.
The tendency at the present time is to ariihmetise mathe¬
matics. The earlier explanation of irrational numbers, like
that of fractions, involved the idea of measurement. Formerly
an irrational number was defined as the expression of the
incommensurable ratio of two geometrical quantities — that
is, as the ratio between two quantities having no common
measure. For the purpose of removing certain logical diflSi-
culties, G. Cantor, K. Weierstrass, B. Dedekind and others
have treated irrational number in a manner free of ratio and
measurement and of all geometrical considerations. This
arithmetical theory of the irrational is now about one quarter
of a century old; but our college text-books contain nothing
of these new ideas; the opinion strongly prevails among
teachers everywhere that the arithmetical theories of the
irrational are not suited for elementary instruction in the
differential and integral calculus, or in analysis in general.
To the teacher of elementary arithmetic the chief point of
interest of these remarks on higher mathematics lies in the fact
that the use of the number concept, which is free of ratio and
measurement, is assuming a more and more central position in
the rigorously logical exposition of the advanced branches.
Colorado College
(\
Studies. '
VOLUME IX.
PAPERS HEAD BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
CCn.ORADO SPRINGS, COLORADO,
MAY. 1901.
s
t)"'
SJ.
y
CONTENTS.
Pace.
(1) Remarks upon Clifford's Proof of Miquel's Theo¬
rem, 1-5
Dr. F. H. Loud.
( 2) La Femriie dans les Chansons de Geste, . h-24
Prop. H. A. Smith.
(5) A Story of Some Teleosts from the Russell Sub-
stage of the Platte Cretaceous Series, Pis. I-III, 25-44
Dr. F. W. Cragin.
THE OUT WEST PRINTING AND STATIONERY OO.
COLORADO SPRINGS, COLO.
I
REMARKS UPON CLIFFORD'S PROOF OF MIQUEL'S
THEOREM.
By F. H. Loud.
The name of Auguste Miquel, on the tongues or pens of
geometers of the present day, occurs most frequently in con¬
nection with the remarkable theorem* which forms the con¬
cluding proposition of the following statement.
Given five lines in a plane, they form ten triangles, whose
circumcircles meet by fours in five points, and these points
lie on a circle.
For convenience of statement, I have combined with
IMiquel's theorem proper an antecedent truth upon which it is
based, relating to four lines. On examination it will be per¬
ceived that if we would build up the theorem from its ele¬
ments we must begin with two lines, in the following fashion;
Given two lines, they have one point of intersection, P^.
Given three lines, we may leave out one at a time, and
thus form three pairs. Each pair has its point of intersec¬
tion, Pj, and the three points lie on a circle Cg.
Given four lines, leaving out one at a time forms four
sets of three, each with its circumcircle Og, and these four
circles meet in a point P4.
Given five lines, they form in the same way five sets of
four, each determining one point P4, and these five points lie
on a circle Cg.
The interest of Miquel's theorem was much increased
when it was shown by W. K. 01ifford,t and later, (though, it
seems, independently) by S. Kantor,J that the series of
propositions thus begun continues true in an indefinite pro¬
longation, defining, for every even number, 2n, of arbitrarily
♦ Liouville's Jour^l, vol. x, p. 349.
t" Synthetic Proof of Miquel's Theorem," Mathematical Papers, p. 38.
i " Ueberden Zusammenhang von n beliebigen Geradenin der Ebene," Sitzungs-
berlchte, Wien, 1878, p. 789.
2
Colorado College Studies.
given lines in a plane, a point Pzn, and for every odd number
a circle C2n+j, with the property that always the point P^n is
common to all the 2n circles C2n—i, and always the circle
Cin+i passes through all the 2n+l points P^n.
Clifford's method is indicated by Salmon,* but as the lat¬
ter author does not enter upon the above-mentioned extension
to more lines than five, I take the liberty of summarizing the
proof of Clifford, though his original paper, which no one of
geometrical tastes should omit to read, is fairly accessible.
An n-fold parabola is defined as a curve of class n-fl,
touching the line infinity n times. Such a curve is rational
and of order 2h, and is determined by 2n-t-2 finite tangents.
It has only one focus; for from the circular point I there can
be drawn only one tangent beside the line infinity, and this
tangent meets its conjugate from in the single real point P.
If the number of given finite tangents is only 2n-|-l, a single
infinity of curves can be drawn, and the focus of each is the
intersection of a ray from I by the projectively correspond¬
ing ray from Jj hence the locus of P is a conic through I
and J; that is, it is a circle. Among the curves of the above
pencilf there are 2ji-|-1 cases of disintegration, viz., an n-fold
parabola may consist of the point in which one of the given
lines meets the line infinity, together with the (n—l)-fold
parabola touching the other 2n lines; and its focus is the
focus of the latter parabola. Hence the 2n-|-l foci of these
special curves lie on the one circle determined by the 2n-f 1
given lines; while, when2n-f-2 lines are given, we may from any
2n-|-l of them determine one circle as above, and all these
circles will pass through one point, viz., the focus of the
n-fold parabola determined by all the lines.
Clifford does not consider, (as do Kantor and P. SerretJ)
the condition under which Miquel's circle breaks up into a
right line plus the line infinity, but a problem essentially
similar is treated by Salmon .§ The statement for the general
* Higher Plane Curves^ p. 128.
t Curves forming a penctZ are usually understood to have in common a number
of points, one less than suffices to determine the curve; here, however, and through¬
out this paper, substitute for common points in this dehnition, common tangents^
:|:Comptes Rendus, 189.
§ Higher Plarw Curves, § U5, p. 127.
Clifford's Proof of Miquel's Theorem. 3
case may be shortly made as follows: The circle which is
the locus of the foci of n-fold parabolas will break up in this
way if the pencil of such parabolas contains one that has
the circular points as two of its contacts with the line in¬
finity. For that parabola can have no finite focus. Thus the
Miquel circle of five given lines is replaced by a right line if
the five lines are all tangents to a curve of class three, order
four, touching the line infinity at the circular points. This
curve is the hypocycloid of three cusps, by some called the
deltoid.
A number of theorems may readily be rea'ched from the
suggestion afforded by Clifford's demonstration.
Thus we might discuss pencils of curves having two real
foci, one of which is fixed, and seek the locus of the remain¬
ing one. A series of theorems would thus be derived where
the locus found would in general be a circle; though in the
first member of the series, namely, the case of the conic
touching two lines and having a fixed focus, the locus is recti¬
linear.* Passing by such partial, though perfectly valid,
applications of Clifford's method, I wish to notice a case
which I regard as interesting, in which a true result is sug¬
gested rather than proved by an argument framed in imita¬
tion of Clifford's.
Let us consider a curve of third class and fourth order,
having a point of contact with the line infinity, and also
meeting the same in the two circular points. It is rational,
and has no inflection, one double tangent, three cusps and
no other double point. No tangent which shall touch the
curve elsewhere can be drawn through I or J, save the line
IJ itself; there is therefore no simple focus analogous to
that of the conic parabola, such as any n-fold parabola
possesses, but there is one and only one focus, the meeting
point of tangents at I and J, and thus of the type exempli¬
fied by the center of a circle. The number of conditions
imposed by the definition of the curve is four,—two given
points, one givem line as tangent, and an unspecified double
tangent. Five more are required to determine a curve, or
♦ Salmon, Conies^ p. 320. Ex. 3.
4
CoLOBADo College Studies.
rather, to reduce the problem of determining it to a finite
number of solutions. Let four of these be supplied by
assigning, in the finite region, lines which the curve must
touch, and a fifth by requiring that the double tangent to
the curve meet the line infinity in a specified point, K.
Then a set of curves is determined, to each one of which one
tangent, is drawn at I and one at J, meeting at a definite
point. Now let K move along the line infinity. We may
regard each curve of the set as undergoing a continuous dis¬
placement and distortion; and if the attention be fixed upon
one such varying curve, we shall see its focus describing a
locus, defined by the intersection of a tangent at I with a
conjugate tangent at J. This separation of the tangents at
I and J belonging to one curve from those belonging to any
other affords an indication that the whole pencil of tangents
through I is resolvable into partial pencils, in each of which
a ray through I is met by a single ray through J projectively
corresponding to it. If this be the case, the locus of each
focus is a circle. But when the point K, in its motion
along the line infinity, reaches the point at which that line
is cut by one of the four given tangents, the curve has four
contacts with lines through K, and being of third class only,
it must break up into the point K and a curve of second
class cutting the line at infinity at I and J, and touching the
three remaing given lines. Such a curve, of course, is a circle,
and its center is the focus of the disintegrating third-class
curve. We have thus the theorem that, when five lines are
given, the centers of the circles which touch three of these
lines lie by fours upon circles which have a common point;
that is, if four given lines be a, 6, c, d, the center of a circle
touching a, b, c and those of one touching a, h, d, one touch¬
ing a, c, d and one touching b, c, d lie on a single circle;
moreover, if a fifth line be added, and the proper single circle
selected for each of the five sets of four lines formed by
dropping one line from the given five, these five circles pass
through a point.
Clifford's Proof of Miquel's Theorem. 5
This theorem is true, as I have elsewhere shown analyti¬
cally;* and is, moreover, the first t'erm of a series of theorems
which would be obtained by replacing the curve of third order
in the foregoing argument by curves of higher order precisely
according to the analogy of Clifford's demonstration. The
argument here given is, however, incomplete as a proof, until
it is shown that the pencils of J-tangents and J^-tangents
break up, as indicated, into separate simple pencils whose
rays have a one-to-one projective relation.
To do this, by purely geometric reasoning would probably
not be easy; at least it may be expected that the demonstra¬
tion would acquire a length and cumbersomeness which
would render it entirely unlike the elegantly, simple argu¬
ment in which the analogous theorem was established by
Clifford.
♦"Sundry Metrical Theorems concerning n Lines in a Plane;" a paper read
before the Am. Math. See. April 28,1900, and subsequently published in the Trans¬
actions of that Society, Vol. I, No. 3.
May 1, 1900.
LA FEMME DANS LES CHANSONS DE GESTE
By H. a. Smith.
I.—Int roduction.
Le temps qui est compris dans cette investigatian peut se
placer, nous croyons, entre 1100 et 1250. Excepts La Chan¬
son de Roland il n'y a gu^re de chansons de geste qui
remontent plus haut que 1100, et si nous donnons aux mots
" chansons de geste " le vrai sens, nous n'en avons pas beau-
coup apr^s la premiere moiti6 du XIII'' sibcle. A partir de
cette date de 1250 la plupart de ces po^mes Merits en imita¬
tion de la vieille chanson de geste sont mieux compris sous
le nom de romans d'aventures. Ce n'est pas done notre
intention d'appuyer aucune assertion importante sur un
texte evidemment compos6 depuis cette dernifere date, s'il
n'est pas clair qu'un tel passage vient d'une 6poque plus
ancienne. Sur ce point il faut peut-etre un pen d'explication.
Le temps suppos6 de la plupart des chansons de geste est
beaucoup plus ancien que la date de la composition. Pres-
que toutes qui sont citi6s ici pr^tendent avoir pour temps le
r^gne de Charlemagne on de son fils Louis. Mais il ne faut
pas qu'on s'y trompe. Les ^crivains k cette 6poque ne
saivaient pas ce que c'est la couleur locale et sauf la l^gende
il n'y avait pas d'histoire. Les conditions et les ■ moeurs
alors sont presque ton jours celles ~du temps de la composi¬
tion. Mais il y a des exceptions notables qui viennent du
fait que les chansons de geste sont le plus souvent bashes sur
des l^gendes, ou elles sont tout bonnement des remaniements
des versions plus anciennes, et quand une coutume fait une
partie n^cessaire de I'histoire, on pourrait s'attendre qu'une
telle coutume se pr^serverait. Une preuve concluante de
ceci se trouve dans le po^me Girart de Rossillon. II y en a
deux versions, I'une beaucoup plus ancienne que I'autre.
Maintenant tous les faits les plus utiles pour notre sujet, qui
La Pemme dans les Chansons de Geste.
7
sent cit^s de la version la plus r^cente, se trouvent aussi
dans la version la plus ancienne.
Peut-6tre un mot d'explication est aussi n^cessaire sur la
valeur de nos textes. II ne faut pas qu'on s'attende k trop
grandes choses de ce titre. Les chansons de geste sont des
po6mes guerriers par excellence, et naturellement on n'y
trouve pas beaucoup de renseignements sur la femme et la
vie domestique. Mais par cela meme, ce peu doit etre d'une
valeur plus grande.
Nous avons pr6par6 une petite bibliographie des po^mes,
qui aura lieu k la fin.
II.—La Jeune Fille.
Si I'on commen^a avec la femme comme M. Gautier com¬
mence avec le chevalier dans cet ouvrage superbe " La
Chevalerie," c'est a dire avec I'enfant dans son berceau, on
serait tr6s embarass6 a tirer quelque chose sur la petite fille
de nos vieilles chansons de geste. Plusieurs de nos cheva¬
liers les plus renomm6s parviennenf k avoir des enfances
dans nos po^mes — cela est I'expression exact parceque
Venfance est toujours la derni^re chose dans la vie d'un
h6ros—mais il n'y a pas, que je sache, une seule enfance
d'une femme. Meme, nous croyons que la petite fille n'^tait
pas toujours le hote le plus bienvenu dans la famille d'un
vieux baron. Ce qui'on voulait avant toute autre chose,
c'^tait un fils, un h6ritier pour bien maintenir le fief et
I'honneur de la famille; et chose triste pour notre sujet, c'est
ce qui arrive toujours. II n'y a pas d'exceptions dans les
chansons de geste.
Cependant on peut deviner que la vie de la petite fille ne
diff^rait pas beaucoup de la vie de ses f r^res. Pile 6tait baptis6e
dans la meme manidre et nous savons aussi, plus tard, qu'ils
6taient instruits 6galement dans beaucoup de choses. Mais
la petite fille devient interessante dans les chansons de geste
seulement quand elle arrive a I'age du mariage.
Si nos vieilles chansons de geste nous laissent dans une
obscurity regrettable a I'^gard de la petite fille, en revanche
elles nous disent beaucoup quand elle devient jeune femme.
8
Colorado College Studies.
Mais avant que nous commencions k d^crire I'instruction
d'une jeune fills, peufc-fetre serait-il bien a fairs son portrait.
C'sst cs qu'on fait toujours dans Iss po6mss. Voici un pas-
sags ds Doon ds Maisnce qui d6crit la bells Nicolstte, une
jsiine fills qui ss fiait, comms toujours, trop volontisrs ii la
bonne foi et I'amour ds I'homms, st qui Is suivit trop
justement aux dangers st la mort, sn rsnon^ant a ses
parents, k ses amis et h sa patris:
"Une pucelle vit aus sa couche seant.
La plus tr6s bale rien de chest sikcle vivant
Vestue d'un samin k terre tralnant.
Les iex ot amoreus et la bouche riant
Le vis lone et traitis, bien fet et avenant:
Blanche et vermeille fu et de si bel jouvent
Qu'ele n'ot que .XI. ans et .1. mois seulement
Longue fu et gresleite et de bel estement.
Par ses espaulez sunt ses biaus chevaus gesant
Qui plus sunt esmer^ que fin or qui resplent."'
C'sst Ik un portrait d'une jeune fills caracteristiqus. Et
il faut Is dire que les poktss smploisnt prssqus toujours les
memes mots pour la psindrs. Ells est toujours grele st
blanche " comms la nsigs " on " comms une flsur," st a des
tresses comms "or esmerk," les ysux sont toujours vairs,
comms dans Raoul ds Cambrai: "vairs ot les ex, ce samble
toz jors ris."" La bouche est petite st les Ikvrss rouges.
Nous ns savons trop pourquoi, mais c'est vrai qu'on ns
trouvs pas psut-etrs une ssuls femms bruns dans toutss les
chansons ds gests.
Le mot vair, qui est employk toujours pour dkcrirs les
ysux d'une femms, mkrits un paragraphs k lui-mems. Sa
signification la plus ordinaire est de couleurs diffkrentes ou
changeantes. II est employk pour une espkce de fourrure de
couleur gris blanc melk.' Mais en dkcrivant les yeux, il sem-
blerait certainement avoir un sens plus prkcis que changeant
ou brillant, parse qu'on n'y emploie jamais un autre mot
pour indiquer la couleur. Maintenant conime les femmes
sont toujours des blondes on attenderait le plus naturelle-
1 Doon de Maience .V. 3623.
2 Raoul de Cambrai .V. .6568.
'Voy. Gautierp. 40L La Chevalerie.
La Femme dans les Chansons de Geste.
9
ment un oeil bleu, et nous croyons que ceci est son vrai sens.
Peut-etre une autre cause pour employer un mot qui signifie
de couleurs diff^rentes pour les yeux bleus, est que dans un
tel oeil nous avons le bleu mel6 de petits points blancs, et si
cette explication est la vraie ce semblerait indiquer plutCt
un oeil bleu blanc.'
II est digne de remarque que dans les chansons de geste
les plus anciennes, on ne d^crit pas longuement les beaut^s
physiques des femmes. On emploie Ih des epithStes homeri-
ques comme "Aelis an clair visage"^ et quaiid on vent
donner une id6e plus frappante de sa beaut6 on ditque "Tut
le palais de sa bealt6 resplent.'" Nous n'avons trouv6 qu'une
seule femme laide dans les chansons de geste. C'est dans
Aymeri de Narbonne, et elle 6tait la femme de cet original
Hernaut qui parlait toujours des choses qu'il ne ferait jamais
et qu'il faisait tout de suite. Entre autres Hernaut dit, "Que
fame rouse n'avroit en son a6,—puis en ot une, ainz lone
terme pass6,—Qu'il n'ot plus laide en une grant cit6:—D'un
pi6 clochait: s'ot .1. oil avugl6,—Si estoit rouse et il rous
par vert6."*
On entend beaucoup aujourd'hui des femmes qui devien-
nent plus instruites que les hommes, mais il semble que
c'6tait vrai aussi au XIP si^cle. Au moins c'est I'id^e que
les chansons de geste nous donnent et on ne salt aucune
raison a douter de leur t6moinage. On pent comprendre
comment cela se pourrait. Le metier d'un homme au moyen
age 6tait la guerre, et il y avait un si grand nombre de choses
a appreudre pour etre guerrier et chevalier accompli, qu'on
n'avait pas de temps pour apprendre a lire et a 6crire, des
choses dont aprfes tout le chevalier ne faisait pas grand cas.
Mais ces memes conditions ne tenaient pas pour la femme,
et on trouve le plus souvent dans les descriptions des jeunes
filles qu'elles savaient lire et 6crire romnn et quelque fois
^ Nous trouvons dans le proven^^al que le mot vair so dit du raisin qui se colore,
et nous y avons la phrase: "A I'uei vaire comme uno pruno vairo." . (Mistral die.
prov.) .
2Raoul de CainDrai .V. 115: ' A6lis au vis clair," et mille fois dans celui-ci et
d'autres pofemps.
®Otinel, V. 343, et dans plusieurs autres po^mes.
^Aymeri de Narbonne, V. 4551.
10
CoLOEADO College Studies.
latin. Tr^s souvent les pontes vont plus loin m6me et
ajoutent des choses qui sent ^videmment des exa^f?6rations.
II sera utile de citer quelques-uns de ces textes. Le po^te
dit de Flordespine en Gaufrey:
0
" Bien sot parler latin et entendre romant
Bien sot jouer as tables as esches ensement,
Et du cours des estoilez, de la lune luisant
Savait moult plus que fame de chest si6cle vivant.''^
Dans Aid:
"Et des cours des estoiles, del remuer
Del refait de la lune, del rafermer
De chou par savoit il quant qu'il en est:
Avisse la ducoise I'en ot moustr^e;^
et dans Berte aus Grans Pi6s:
"Avolt une coustume ens el tiois pays,
Que tout 11 grant seignor, li conte et 11 marchls
Avolent entour aus gent frangolse tous dls.
Pour aprendre fran§ols lor filles et lor fils."'
Mais la plus remarquable est Mirabel, amie d'Aiol:
Ele sut bien parler de XIIII latins:
Ele savoit parler et grlgols et hermln,
Flamenc et borgengon et tout le sarrasln,
Poltevln et gascon, se 11 vlent a plalslr."^
Mais ce sent beaucoup de langues meme pour une femme.
II faut se tenir compte des exaggerations, mais il y a ici
beaucoup qui est evidemment vrai. Sans aucun doute
savait-elle lire et ecrire, et peut-etre un pen de latin. Au
moins elle pouvait comprendre des mots dans son psautier.
Elle pouvait calculer et donner les noms des principales con¬
stellations. Sur ce dernier point il n'y a gufere de doute. II
y a trop grand nombre de passages qui indiquent I'interet
dans I'astronomie, si Ton pent la nommer ainsi a cette
periods. Aussi etait-elle un pen medecin, parcequ'elle con-
naissait des herbes qui donnaient des guerisons merveilleuses.®
'Gaufrey, V. 1793.
2Aiol, V. 268
' Berte aus Grans Pi6s, V. 149.
tAiol, V. 5420.
® Gaufrey, V. 3923. La Mort Aymjri de Narbonne, V. 1988, ou on fait mention
d'un onguent, d'un vin blanc et de phrases rOligieuses et du signe de la croix, etc.
La Femme dans les Chansons de Geste.
11
Quant aux choses qui sent particuliferes k la femme, elle
savait coudre, filer et broderd Elle taillait les vStements de
la famille. Pour ses amusements elle jouait aux eschecs^
comme ses fr^res et aussi comme eux elle savait monter a
cbeval et chasser avec le faucon. Alors il y avait la danse et
le chant. La derni^re chose, et ce qu'elle savait le mieux,
c'6tait sa religion. A croire les chansons de geste, il n'y a
personne plus devote que la femme du XII" sifecle.
Nous croyons que les jeunes filles 6taient le plus souvent
instruites dans la maison par la mfere on par une institutrice.
Mais meme ti cette 6poque quelques-unes 6taient Gev6es dans
les convents.®
Les devoirs de la jeune fille ^talent sans doute essez nom-
breux. En outre de ceux que nous venous de citer, elle
faisait de coutume beaucoup d'ouvrage de la maison. Avec
sa m^re elle avait la tenue des lits,'' et des habits de la
famille, et s'il y en avait besoin elle n'h^sitait pas d'6tendre
ses soins jusqu'a lAcurie. Elle aidait ti armer et h d6sarmer
son seigneur et les hbtes,® et meme a les d^shabiller et leur
donner des bains.® A lAgard de ces derniers devoirs il ne
faut pas juger des actions semblables par les memes regies
que celles de notre soci6t6. La soci6t6 au XIP si6cle 6tait
k certains 6gards plus libre que la nbtre. Mais surtout il
^En parlant de Berts devenue coutouri^re, on dit:
De ce fairs en s'enfance avait 6t6 aprise
Bien scut tailler et coudre et braies et chemise.
S'elie sout tel mestier ce ne fut pas mervoille
Quar Augustus C6sars fist bien le cas paroille
II fut vaillans et saiges et regna moult grant pi^ce:
Mas il n'out oncques tile ne cosine ne ni^jce;
Qu'il ne f6ist aprendre quelque mestier fairs."
(Girartde Kossillon, V. 2371).
2"J'ai une fills qui moult a de biaut6;
Des eski^s set a moult grande plent6;
Ainc ne le vi de nul homme mater."
(Huon de Bordeaux, V. 7427).
^Dans Raoul de Cambrai une jeune fille d'un baron est brtiiee dans un convent.
V. 1493. M. Gautier cite d'autres autorit6s.
Uiol, V. 7306.
®" File " dit il, " ce paien te comant—Donez li armes trestout k son talent —Ces
III puceles armerent Otinel " lOtinel, V. 344). De tels passages sont assez nom-
breuz daos les poemes.
0 ".LX. furent filz de moult haute gent,
Aprester font les bains tot main tenant
Ni a si poure tant ait poi tenement
N'ait sa pucelle devent lui enpresant
Fills de conte ou de prince ansument
Qui bien les servant et font h lor talent "
(Les Enfance Vivien, V 5147).
12
CoLOBADO College Studies.
n'y avait pas de pruderie, et nous croyons que ces choses-lk
sent, pour la plupart, de bonne foi, quoique il soit possible
qu'on en ait fait des abus. Au moins on les trouve dans les
textes les plus irr^cusables.
Sur plusieurs de ces points il sera utile de donner
quelques passages d'Aiol, tir^s de la premiere partie, oeuvre
du XIP si^cle, dont nous croyons l'autorit6 assez stabile.
O'est oil Aiol est re^u dans la maison de sa tante par sa
cousine, Luisane, qui ne sait pas qu'il est son parent;
El le prist par I'estrier par grant amor:
"Amis ost6s vostre elme, denes le nous,"
La bale Luisane al cors legier
Un escuier commande le sien destrier
Le maistre senescal a apel^;
Se li fist le mangier bien conreer,
Et vint a Marchegai par esgarder,
S'aplanoie ses crins et ses cost^s;
La Pueele s'en torne al cors gentil
La sist le lit Aiol par grant delit;
Aiol en apela, se li a dit:
"Damoiseus, ven^s ent huimais dormir"
Par le poin le mena dessi al lit.
Puis le fist descauchier, nu devestir
Et quant il se coucha bien le couvri:
Douchement le tastone par endormir.
Mais bele Luisane bien le servi;
Douchement le tastone la demoisele;!
Ces derniers vers font mention d'une coutume si singu-
li^re qu'on pourrait en douter si les textes le permettaient.
Pour faire endormir les hbtes les femmes les tatonnent ou les
massent.^ II ne semble pas qu'il y avait aucune mauvaies
intention dans cet usage, parceque nous y voyons des dames
comme Guiborc qui sont audessus de tout soup^on, mais
c'^tait aussi une coutume tr^s dangereuse, comme on voit
dans le cas d'Aiol oil Luisane est Uprise d'amour et lui fait
des avances qu'il repousse.
Un des devoirs de la jeune fille que M. Gautier donne
lAiol, V. 2044.
2"QaeQS Aimeris est ses Us aprest^s—en une cambre on molt avait biaut6s;—
toute unit fa de Gaiborc tastones." (AUscans, V. 4261). C'est quelque fois fait par
un homme comme on voit de ce passage dans Li Charrois de Nymes: " Looys, sire,
dit Guiliaume li bers —moult t'ai servi par nuit tastoner." M. Gautier cite aussi un
passage en Girart de Bossillon.
La Femme dans les Chansons de Geste. 13
dans "La Chevalerie" 6tait le service de la table. Pour des
preuves il donne les memoirs de Sainte-Palaye. C'est I'oc-
cupation qu'on attendrait le plus naturellement de la femme,
maisuous n'avons pu en trouver des preuves convaincantes
dans les chansons de geste. Dans Fierabras nous avons un
passage qui dit que "Les pucieles les servent h joie et k
bont6—k manger et h boire eurent & grant plenty."' Mais
dans ce cas comme dans tons les autres qu'on trouve oil il
est certain qu'une femme a servi k la table les circonstances
sont telles qu'il 6tait n6cessaire. lis sont ici dans la prison
et il n'y a pas d'autres personnes pour les servir. Ce n'est
pas un r6pas ordinaire.
De I'autre c6t6 il y a mille passages oil un jeune homme,
un 6cuyer ou meme un chevalier d^coupe et sert ii manger.
On sait de plus que c'est toujours une des choses cit6es pour
I'instruction d'un page ou d'un aspirant ii la chevalerie, celle
d'apprendre k d^jouper et k servir k la table.
Aussi tons les cuisiniers que nous avons pus trouver sont
des hommes.^ Que la chatelaine se chargeait du gouverne-
ment de la cuisine et du menu, on ne pent douter, mais
qu'elle et ses filles faisaient I'ouvrage ou qu'elle avait meme
des servantes pour le faire, on ne pent trouver aucune indi¬
cation. Le contraire serait indiqu6. On sait que c'^tait du
plus vieux temps un honneur k servir k la table d'un roi ou
chef, et on voit de cette circonstance comment cette coutume
se pr6serverait; et c'^tait au XIP sikcle toujours un service
le plus honorable. Mais du fait que les femmes ne cusaient
pas, si c'6tait un fait, nous ne voyons aucune explication
suffisante. Si c'est vrai, il y avait aprks tout de petites
choses qui feraient desirer aux femmes d'aujourd'hui de vivre
au XIP sikcle.
Avant que nous arrivons k la question du mariage de la
jeune fille, il reste encore k parler d'elle comme amante;' et
c'est ici qu'on voit une grande difference entre les femmes
des plus vieilles chansons de geste et celles de la premikre
moitie du XIIF sikcle, ou mkme de la dernikre partie du
XIP. C'est ce qui paraitra plus tard.
' Kierabras, V. 2215. 2 Voy. Aiol, citfi audessus.
14
Colorado College Studies.
D'abord nous n'entendons pas dire que les mariages
6taient toujours des mariages d'amour, ou meme que c'^tait
la condition ordinaire. On pent voir que la n6cessit6 decide
trfes souvent le mariage et que les volont^s des partis con-
tractants comptent pour peu de chose. Cependant 11 est
facile ^ voir dans les pennies que le mariage d'amour est
I'id^al, s'il n'est pas toujours la pratique.
La premiere question qui se pr^sente est sur quelles
qualit^s est bas4 I'amour au XIP si^cle. Nous croyous qu'il
est tout facile a r^pondre. Un homme aimait une femme
pour sa beauts, mais certainement une femme aimait un
homme a cause de son courage. On trouve cette id^e
partout. Qu'un chevalier donne de bons coups, c'est I'essen-
tiel. Par exemple, prenez le cas de la belle Beatrix, qui fut
Uprise d'amour pour Bernier en Eaoul de Cambrai. Si
Bernier avait des qualit^s exceptionnelles plus qu'un autre
au commencement, nous n'en savons rien. Mais il aurait eu
certainement des petits d^fauts selon les id^es de notre
temps. D'abord il 6tait batard et avait 6t6 I'ennemi acharn6
de.p^re de Beatrix. II avait tu6 le cousin Raoul et les fr^res
de la jeune fille. Aussi ses combats n'avaient pas 6t6 tels
qui augmentent un bel ext^rieur. Sans compter ses nom-
breuses blessures au corps et aux membres, pour commencer
Raoul lui avait bris6 la tete d'un gros baton, Gueri avait
perc6 son visage de I'os de la jambe d'un cerf, Gautelet avait
Ot6 une partie g6n6reuse de son cuir chevelu, et pour finir
avait d6coup6 son oreille droite avec la chair d'un "demi-
pied" de son visage. Certainement des choses comme cela
feraient penser deux fois a une belle d'aujourd'hui.
Mais de I'autre cot6 il 6tait un des plus grands combat-
tants du pays et quand lui et Gueri se reconciliarent, d^s
que Beatrix a entendu son nom, elle dit " heureuse la dame
qui sera sa mie car il a grand prix de chevalerie," et elle va
I'embrasser dans la premiere entrevue. L'auteur ajoute une
phrase qui dit tout en deux mots: "Ci s'entracolent nus
n'en doit mervillier,— car ele est hele et il hons chevalier
Voulez-vous un example plus fort! II n'en manque pas.
* Raoul, V. 5666.
La Femme dans les Chansons de Geste. 15
Dans le po^me, Aid, le h^ros prend la jeune fille d'un roi
paien et Temm^ne captive. Mais, chose pas ordinaire, elle
ne vent pas devenir la femme du jeune chevalier, et cherche
toujours k 6chapper. II y avait un roi paien dont elle 6tait
amoureuse. Un jour tandis qu'Aiol fatigu6 dort sous un
arbre elle voit approcher quatre de ses parents qui les
poursuivent. Elle est joyeuse, elle va 6chapper, mais en
vrai femme elle ne veut pas laisser Sgorger un chevalier en
sommeil. Elle le secoue et lui dit de s'enfuir. Vous com-
prendrez sans doute la consequence. Aid se Ikve terrible,
monte sur son cheval et tue I'oncle, le frkre et les deux
cousins devant les yeux de la belle captive. Vous croyez
qu'elle pleurait de belles larmes. Sans doute, mais voici ses
pens6es: "Dieu! quel bon chevalier! C'est mon avis s'ils
avaient 6t6 vingt, il les aurait tu6s tous:" et elle ajoute:
"Sire ven6s vous ent car je sui vostre drue." C'est une
conversion soudaine et par explication le pokte nous dit:
"Que feme aime tost home qui bien fiert en bataille.'"
C'est done I'homme le plus brave qui a toujours la plus
belle dame, et cela ne doit nous surprendre comme nous
savons, plus tard, au moins au temps des chevaliers errants,
que I'homme le plus brave s'6tait accoutum^ d'enforcer ce
petit point avec la lance et I'ep^e, Aussi dans le douzikme
sikcle la plus belle femme 6tait trks souvent k celui qui avait
la force pour la prendre.
Est-ce que la femme avait un vrai amour pour ce cheva¬
lier duquel elle pense principalement au renom ? Dans les
plus vieux pokmes cela est sans doute. Voici une incident
de la chanson de Roland, la plus vieille et la plus belle de
tous. Aprks sept longues annkes de batailles, I'armke fran-
gaise revena d'Espagne. Tristement, parcequ'ils out laissk
en Roncevaux le plus grand chevalier du monde, Roland, le
hkros de la France, et avec lui Olivier, tous les douze pairs
et vingt mille hommes, la fleurde I'armke. L'empereur vient
k sa capitale, "Muntet el palais, est venuz en la sale,—as li
venue Aide, une bele dame,—go dist a I'rei: "U est Rollanz
li catanies,—Ki me jurat cume sa per k prendre?"—Carles
Uiol, v, 5597.
16 ■ Colorado College Studies.
en ad e dulur et pesance,—Pluret des oilz, tiret sa barbe
blanche;—"Soer, chere amie, d'hume mort me demandes,—
jo Ten durrai mult esforciet escange:—c'est Loewis, mielz ne
sai jo qu'en parle:—il est mis filz et si tiendrat mes marches,"
—Aide respunt: C'est moz mei est estranges,—ne placet Deu
ne ses seinz ne ses angles—apres Kollant que jo vive
remaigne!"—Pert la culur, chet as piez Carlemagne,—
Sempres est morte, Deus ait mercit de I'anme!
La douleur d'Heluis, la fianc6e de Raoul de Cambrai,
quand elle le regarde pour la derni^re fois sur la bi^re est
presque aussi grande. "Biax dox amis" dist la bele en
plorant—" n'avrai signor en trestout mon vivant," voeu
qu'elle tiendra toujours.''
Malheureusement il faut se tourner de ces beaux exemples
au type de la jeune fille que les pontes du XIII° ou de la
dernifere partie du XIP si^cle nous ont donn6. If faut com¬
parer Florete en Floovant avec Aude pour voir combien sont
plus has les sentiments. Florete a 6t6 I'amie de Floovant
mais il avait donn6 sa parole Maugalie, et Florete se plaint
k son pfere en bons termes. "Elle n'aura jamais mari en
trestot son vivant" sauf Floovant. Mais ce dernier s'avance
au roi, all^gue son engagement avec Maugalie et demande la
main de sa fille pour son 6cuyer. Le roi y consent et
demande Florete son avis. "Sire," dit la pucelle, "je le
voul ausimant;—Quant autre ne pout estre, Richier me
commant."' C'est vrai que Richard n'6tait pas moins
courageux que son maitre!
Dans Elie de Saint Gilles on vois meme sc^ne rep6t6
dans tons les details oil Rosambnde la liberatrice d'Elie se
console sans beaucoup de peine et imnibdiatement demande
Galopin son bcuyer;* et on pourrait rbpbter ti plaisir des
passages pareils. Quelle difference entre ces reponses et
celle de la belle Aude! On voit qu'il n'6tait plus le mari
voulu mais un mari quelquonque.
^La Chanson de Roland, V. 3705.
2 Raoul de Cambrai, V. 3713.
« Floovant, V. 2348.
*Elie de Saint-Gilles, V. 2689.
La Femme dans les Chansons de Geste. 17
Cependant si la l^g^ret^ 6tait la seule faute qu'on pour-
rait reprocher k la classe des heroines cr66e h ce temps on
serait bien heureux. Mais les pontes n'h^sitent point k les
peindre d'une efPronterie et d'une impudicit6 horribles. II
y a une ressemblance bien forte entre toutes ces jeunes filles,
et Ton pent bien croire qu'elles 6taient copi6es aprfes quelque
mauvais type qui jouissait d'une grande c6l6brit6. Elles
sont on ne pent plus d6shonnetes et font ton jours des
• avances k leurs amants. Elles n'h^sitent point h employer
tout moyen pour ariiver h leur but. Floripas en Fierabras
s'efforce a faire tuer son p6re parcequ'il ne se convertit pas,
et sa m6chancet6 est tout-k-fait incroyable.' II y a une foule
d'autres presque aussi m6chantes. Sans doute les pontes ont
dit beaucoup de mensonges dans ces po^mes; mais s'il y a
des exaggerations l&-dessus, nous croyons qu'il y en a aussi
des raisons. Nous y reviendrons plus tard.
III.—Le Mariage.
Dans un des vieux poemes, I'auteur se fache beaucoup
contre les manages prematures. Ses mots sont dignes d'etre
cites:
"Baron a icel tant dont V0U8 m'oes center
Nus horn ne prendrait feme, s'avoit .XXX. ans pass^
Et la pucele encontre aussi de bel a^;
Mais puis est avarisse et luxure months.
On fait mais .II. enfens de .XII. ans asambler."®
On est souvent en peine k dire dans les passages sem-
blables si I'auteur parle rkelement d'un fait ou si ce n'est pas
tout bonnement une expression du regret, qu'on trouve
partout, pour " le bon vieux temps," mgme quand "le bon
vieux temps" est le plus mauvais. Mais nous croyons qu'il
dit ici, avec un pen d'exaggeration, une verite historique.
La date du passage est a peu prks 1200, et a ce temps sous
I'influence du systeme feodal beaucoup de mariages etaient
sans doute d# trks bonne heure. L'amante de Doon de
^ Fierabras, V. 5955. »
2Aiol V. 1696.
18
Colorado College Studies.
Maience, Nicolette "n'ot que XI. ans et .1. mois seulement."'
Flordespine en Gaufrey avait ".XIII. ans et demi"^
L'h^roine de Parise la Duchesse n'avait que XV ans quand
elle fut chass^e de son pays et elle 6tait marine peut-6tre une
ann6e.' II y a une foule d'autres cas ou la femme est aussi
jeune.
On salt qu'il 6tait k I'int6r6t du roi ou du seigneur f6odal
au moyen age, quand un de ses barons mourut et laissa une
jeune fille heriti^re, de la donner en mariage aussitbt que
possible, pour obtenir un homme pour d^fendre le fief et
pour ses guerres. Et c'est cette circonstance qui faisait un
si grand nombre de mariages pr6matur6s.
Mais avant le XIP siade le fief n'^tait pas>b6r6ditaire.
Nous croyons meme voir qu'il ne I'^tait pas tonjours au XIP
siade. Alors il se pourrait tr^s bien qu'avant ce siade les
mariages n'^taient pas de si bonne heure. De plus, un
examen soigneux des textes les plus vieux, comme Roland et
Aliscans, appuie cette id6e. Le r6le des femmes dans ces
po^mes est plutbt le r6le d'une femme d'un age mur, que
d'une jeune fille de douze ans. C'est vrai que les femmes a
cette 6poque daient de bonne vigoureuses et cet age de
douze. ans n'^tait pas du tout aussi jeune qu'il est a
present.
Nous avons daja vu que dfes que le fief devint har6ditaire
on arrivait a se marier trfes jeune. Cela evoque la question
de qui faisait le mariage; et en tli6orie au moins, si non
toujours dans la pratique, c'est facile a r^pondre. C'^tait le
roi ou le seigneur f^odal. La femme et le fief 6taient
inseparables et c'6tait tout naturel que le seigneur eut ce
pouvoir. Cetait son moyen de payer ses chevaliers comme
on le voit dans tons les poames. Le passage ou Charlemagne
dit qu'il donnerait un autre mari a Aude a ete deja cite, et
dans le meme poeme I'emir incite les paiens a la bataille par
la promesse de belles femmes et des fiefs.* Enfin toute cette
^ Doon de Maience V. ^630.
2 Gaufrey V. 1797,
' Parise la Duchesse. *
♦Roland V. 3397.
La Femme dans les Chansons de Geste. 19
histoire de batailles terribles et de brutality en Baoul de
Cambrai se base sur ce droit du roi. Ce n'6tait pas seule-
ment un droit mais c'6tait aussi le devoir du roi de donner
des femmes k ses chevaliers et des maris aux jeunes filles
h6riti6res, et on voit ces derni^res qui viennent a la cour
" pour demander mari." C'est ainsi que la belle Ayglentine
de Gui de Nanteuil est venue "pour querre mariage" et
quand I'empereur allait la donner ii un homme qu'elle ne
voulait pas—II eut re§u un petit cadeau de mille "mars
d'or. Comment les historiens se sont sottement tromp6s en
Charlemagne!—il s'§leva une guerre pour sa possession.
Cependent il n'y a gu^re de doute que de bonne heure dans
le XIIP si^cle ce droit n'^tait pas aussi rigoureusement
enforce, et peut-etre ce vers trouv6 dans le passage que nous
venous de citer 6tait k pen prks exact: "A moillier la
prendra si le roi le consent.''''^ C'est Evident que le consente-
ment du roi 6tait toujours suppos6 n^cessaire mais comme
ici il ne pouvait trks souvent I'enforcer. Sur cette question
du mariage la femme avait beaucoup de fois de petites prefer¬
ences et quelquefois elle savait les obtenir." Mais il y a
plusieurs examples ou la femme etait forcee h se marier a un
homme qu'elle haissait.'
Trks souvent sans doute pouvait-elle se soustraire de la
dure necessite d'un tel mariage, mais il semble que ce ne
serait ordinalrement qu'avec la perte de son heritage. II fut
ainsi qu'Ailis etait desheritee en Kaoul de Cambrai. Le
droit du roi est evident. II parle d'Aiiis qu'il voulait donner
h un chevalier: "Et s'ele i faut, trkstot par son outraige—
S'irai saisir la terre et I'eritaige."* Comme on pourrait
croire c'etait la cause la plus frequente des guerres feodales
comme c'etait aussi un moyen de confirmer la paix.
•Gui de NaQteuil V. 586.
2La demoiselle a par la main saisi,—Gui dist le rois, ceste aurez en baillie;—
Lors elle respondi com fame courroucie" Par ma foi, Gui, toz pensez grant folie,—
Qu ja n'aurez de moi seignorie,"—Dist I'empereres: "voz ditez grant folie,—(Ju'il
voz convient faire ma commandie "—Mais uns proverbes noz aprent et chastie
Engiens de fame maint saige home cunchie." C'6taitcela qui arriva ici et ce uAtait
pas le seul exemple. (Gaydon V. 8569).
'Raoul de Cambrai V. 6836.
■•Daurel et Beton V. 644. Raoul de Cambrai V. 151.
20
Colorado College Studies.
En dehors des conditions cit6es il faut de plus que les
partis ne soient pas des parents, ni des parents du sang ni
des parents spirituels,' parcequ'il semble que les parrains du
bapt&me contract^rent une parents qui interdisait au mariage
de meme qu'une parents du sang.
Dans cette connection il faut mentionner qu'.un grand
nombre de mariages 6tait entre des barons Chretiens et des
princesses paiennes, et quelque fois entre une chretienne et
•un paien. II va sans dire que dans ces ,cas les parens s'6taient
convertis et baptises. L'id^e qu'il pouvait 6tre une union
entre deux partis de religious diff6rentes n'entra jamais dans
la tete d'un homme du moyen age. Quand une femme fut
baptisee il 6tait la coutume de changer son nom. Dans la
Prise d'Orenge le nom d'Orable est chang6 en Guiborc.'
Au bapteme, la femme 4tait d^vetue et plong6e dans les
fonts.' Elle avait des parrains et des marraines comme un
enfant.'
Selon les id6es de l'6glise il fallait le libre consentement
des partis contractants pour faire mariage I6gal, mais sous
un r6gne de la force les officiaux de I'^glise 6taient tr^s sou-
vent forc6s a se plier,^ et il y avait des mariages tr^s centre
la volenti de la femme. Mais au moins ce n'6tait pas I'id^al.'
Enfin comme concession a la femme, on pent ajouter que les
partis seront a peu pr^s de meme fiige. II y a beaucoup de
passages ou la femme exprime son aversion ti un vieux
homme.®
1 "(^ue je suis ses cousins mol ne pent avoir mie" (Aid V. 8120). Dans Elie de
Saint-Gitles apr^s Rosamonde eut sauv6 Etie, et il 6tait sur point de finir leurs
amours en I'^pousant il apprit que le mariage 6tait impossible parceque lui et sa
famille eurent de ses parrains au baptOrae. '"Signor" che dist Elies A m'amie
m'espous6s"—"vasal" dist archevesque, "de folie parJ6s"—che ne poroit soffrir
sainte crestient6s,—voyant vos ieus trestous I'as aidiet a lever—et es saintismes fons
beneir et sacrer " (Elie de Saint-Gilles V 2672).
2 " II la baptisent en Tenor Dame d6Li nom li otent de la paienet6—A nostre loi
la fontGuibor nomer (Prise d'Orenge V. 1868).
3" Adonc s'est desvestue la bele o le chief blon:—En la cuve Tont mise li nobile
baron.—L'archevesque Turpin commenche une lechon;—la bele batisa u nom Saint
Symeon,—Garins fu son parrain et Do et Salemon-Onques au baptizier son nom n'y
canja on—Que ne le vout souffrir Berart le gentis hom " (Gaufrey V. 9146). OtinelV.
626. Fierabras V. 5998.
^Raoul de Cambrai V. 6455.
® Mes une chose sachieg qu'est veritez—molt est li hom fox et musarz provez.—
Qui feme prant outre-ses volentez." (Ayraeri de Narbonne V. 2392).
®"Car il est vieux, s'a la barbe florie-ne le prendroie por a perdre la vie."
(Aymeri de Narbonne V. 2474). " N'ai cure de viellart qui le pel ait froncie" Elie de
Saint-Gilles V. 1735. Prise d'Orenge V. 628.
La Femme dans les Chansons de Geste. 21
II reste encore k d^crire la fagon d'un mariage au XIP
si6cle. Un bon example est le mariage d'Hermenjart dans
Aymeri de Narbonne dent il n'y a aucun point important qui
ne soit pas appuy6 par nos meilleurs po^mes.
Aymeri envoya une ambassade des plus hauts barons de
son pays.au roi, Boniface, fr^re d'Hermenjart. Les ambas-
sadeurs firent la demande de la main de la soeur en lui
promettant un riche douaire et en judicieusement menagant
le fr^re de la guerre s'il refusa. Le roi acceda volontiers et
demanda I'avis de sa soeur. Bien qu'elle ne d^sirait mieux
elle dit que son amant devrait venir la prendre. Ce
fut Ik une modestie qu'on ne voit pas chez beaucoup
d'h^roines.
Aymeri vint et ils furent fiances. Les fiangailles 6taient
tout bonnement une promesse faite entre les deux partis de
se prendre comme mari et 6pouse. Le plus souvent c'^tait en
forme d'un serment fait sur les reliques des saints ou sacr6
par un pretre.' Quelquefois le pkre et I'amant s'engageaient
mutuellement, I'un k donner et I'autre k prendre la femme
comme 6pouse.^
M. Gautier fait une difference ici et nomme ce dernier cas
une fois tandis que les fiangailles sont le libre engagement
des amants ou entre la volont6 de la femme. Mais le plus
souvent les deux etaient le meme, et oil le serment 6tait
seulement entre les amants c'^tait presque toujours ou la
femme n'avait pas de parents presents. Ordinairement le
roi ou parent prenait la jeune fille par la main et la donnait au
chevalier;' et quelque fois on ajoute que le pretre le.sacra,
ou qu'ils "s'entrejurkrent." C'est possible que les fiangailles
6taient souvent faites dans I'^glise,* mais il faut garder de les
^Turpins li archevesque, h la chiere membrie
A demand^ Berart si la dame li gr6e.
Oil, chen dlst Berart, de cuer et de pens^e.
Etvous? dist archevesque douche dame sen^e,
Oil, dist Flordespine, bien me plest et agr^e.
Adonques la 11 a Tarchevesque affile.
(Qaufrey V. 7170).
2"Sor une table font les sains aporter; Ileuques font les sairement jurer,—
Bernier del prendr#^et Gueri de donner" (Raoul de Cambrai V. 5838).
'(Aymeri de Narbonne V. 3404).
<"Sire R. dist la franche pucele,—vos me jurastes dedens une chapele." (Raoul
de Cambrai V. 3683).
22
CoLOBADo College Studies.
confondre avec le manage. C'6tait tout bonnement un
engagement publique, et il n'y avait pas de temps fixe de
jusqu'au manage.
On parle quelque part de la coutume de donner un
anneau aux fiangailles, mais nous n'avons pu en trouver des
preuves suffisantes que c'6tait un usage commun. En Gay-
don cit6 pour appuyer ce point, ce fut envoys par la dame
au amant pour le reconnaitre,^ et en Girart de Rossillon oil
la reine eut donn6 un anneau k Girart, ce n'^tait qu'un
t^moinage d'amiti6. Dans les deux ou trois instances ou il
6tait r6element donn6 comme gage d'amour on ne voit aucune
raison k le croire une cotltume g^n^rale plus qu'un autre
cadeau dont nous avons beaucoup d'exemples; et nous
croyons que I'usage g^n^ralS 6tait plus tard. Car s'il avait
6t6 ordinaire au XIP si^cle rien n'aurait fait une plus grande
impression sur les esprits des podtes, comme on voit a I'^gard
de I'anneau du mariage.
Les mariages 6taient presque toujours dans I'^glise et
Fheure ordinaire 6tait le matin. On allail k I'^glise k clieval
avec nn cortege nombreux.' Les femmes montaient des
mules qui 6taient presque universellement la monture de la
dame.® Elles montaient une selle de femme comme
aujourd'hui et on parle souvent de sa magnificence.*
Dans l'6glise le mariage 6tait sacr6 par un pretre et le
mari donnait un anneau k la femme. Ce semble avoir 6t6
une partie frappante de la c6r6monie puisque la phrase
"dame 6pous6e de I'anneau" est un lieu commun.
Apr^s le mariage il y avait une messe et le parti retour-
nait au chateau. C'6tait pendant cette rentr^e de I'^glise
que les jongleurs, toujours si nombreux aux mariages—des
gens rus6s qui savaient cueillir les "deniers"—jouaient
1 Gaydon V. 8668.
2 Pour tous ces faits: Aymeri de Narbonne V. 4420. Baoul de Cambrai V. 6070.
Aye d'Avignon V. 4100.
sUne moult riche mule 11 ont apparellie—La sele fu d'ivoire, s'est & or eataillie"
(Gaufrey V. 2021).
Ele met le jamble outre par grant nobilit6; le piet met es estriers, esperous
ot dor6s" (Aiol V. 7488). Sans doute ordinairement )a femme portait une robe
differente pour monter & cheval: " Jehennete et Mai tine ont lor dame lev^e—come
pour cbevaucher I'ont bleu atournOe " (Gui de Nanteull V. 1563).
La Femme dans les Chansons de Geste. 23
leur plus belle musique. C'6tait alors que le jeune mari
devenait si liberal et donnait quelquefois son clieval ou son
manteau au chanteur/
Pour les graiides fetes apr^s le mariage qui duraient de
huit jusqu' a quinze jours on avait la coutume de dresser des
tables au milieu de la plaine. II va sans dire qu'il y avait
des joutes, des danses, des chants et beaucoup de r^jouis-
sances. La dernifere sc^ne 6tait tr^s belle. C'^tait ou le
pr^tre venait b^nir le lit des nouveaux marife.'' Alors
les femmes couchaient la jeune dame' et la journ6e 6tait
finie.
II n'y a gu6re des mesalliances dans les chansons de geste.
Le cas de Bernier qui 6tait batard et qui se maria a la fille
d'un comte a 6t6 d^jk cit6.* Aussi quand Aiol allait cher-
cher fortune la cour de Louis un baron voula lui donner sa
fille qu'il refusa parcequ'il 6tait pauvre.'
Un exemple plus parfait est dans Hugues Capet. Le
h^ros 6tait surnomm6 le boucher, parceque c'^tait le metier
de sa famille. Le pofeme est une histoire des exploits
merveilleux par lesquels un homme de si basse famille pouvait
arriver fi se marier avec I'h6riti6re du trhne de la France.®
Mais ce pofeme fut 6crit vers le milieu du XIV° si6cle quand
1 Raoul de Cambrai V. 6089.
2 L'evesque va Testole h son col afubler—Lor lit vint benelr le soir apr^s souper"
(Aye d'Avignon V. 4115).
®Passe Rose couchiferent les dames du roion." (Gaufrey V. 7415).
Dist B. vos savez bien que je sui de bas lin,
Trop est haus bom 11 riches sors Gueri.
D'avoir sa fille n'iert ja par moi requis."
(Raoul de Cambrai V. 5704).
®" Sire che dist aiols, onques mais n'oi tel:
Ja me douge forment que vos ne me gabes.
Je n'ai en nule ters ne chastel ne chit6,—
Trop povre mariage avis or esgard^"
(Aiol V. 1781).
®Dans Hugues Capet il y a un point utiressant ^ I'egard des jeunes filles
hlriti^res. Hugue Capet 6pousa I'hlriti^re du trOne et devint roi. L'auteur dit
qu'apr^s son av^nement un parlement de tous les barons d^cida que dor^navant
seulement les h^ritiers m&les pouvaient prendre la couronne. II y a un air histori-
que dans le passage.
Les 6diteurs out 6tabli que ce po6me fut 6crit apr^s 1312, et on trouve dans
I'histoire qu'il y avait un 6tats g^nlraux en 1316 qui donna un tel arrOt. et que pen¬
dant les quatorze ann^es suivantes les femmes h6riti6res 6taient excludes trois fois
de la couronne de France, les premieres examples oii la loi s'appliquait.
II semblerait tr^s probable alors que le passage cit6 fut fondl sur I'histoire et
que le po^me fut 6crit apr^s 1316 et puet-Otre plu sieurs ans plus tard.
24
Colorado College Studies.
la condition de la bourgeoisie 6tait beaucoup plus 6lev6e.
Un pareil sentiment aurait 6t6 impossible an XIP si^cle ou
on voit un tel m^pris du petit peuple que les pontes
avaient toujours soin de faire une naissance noble pour les
h6ros vulgaires comme Kenouart en Aliscans. Nous n'avons
pas trouv6 un seul texte honorable oil un homme noble se
maria k une femme de basse naissance.
(To be concluded in Vol, X of Colorado College Studies.)
A STUDY OF SOME TELEOSTS FROM THE RUSSELL
SUBSTAGE OF THE PLATTE CRETA¬
CEOUS SERIES.
By F. W. Cragin.
Science owes to the Reverend Mr. H. C. Bradbury the
careful preservation of a specimen of Syllcemus latifrons
from the Cretaceous of Kansas; and the writer is especially
indebted to him for the use of it in paleontological research.
It is but justice to Mr. Bradbury to say that it was submitted
for study long ago, at a time when all that was known of this
interesting fish-form was comprised in Cope's description
and figures of the type-specimen, and that preliminary studies
and drawings of Mr. Bradbury's specimen were made by the
writer some years ago, but were not then published. Impor¬
tant supplementary knowledge has quite recently been added
by Mr. Alban Stewart in his paper on Kansas Cretaceous
Teleosts, in Volume VI. of the University Geological Survey
of Kansas. As the Bradbury specimen throws still further
light on both genus and species, as well as confirms in most
respects Cope's and Stewart's studies, atfording together with
these a fairly complete knowledge of this fish, the writer
here presents revised generic and specific diagnoses in which
the results of his own and renewed studies are incorporated
with the data of the authors named.
Family SYLL/EMID^.
Type-genus, Syllcemus Cope.
As regards the systematic position of the genus Syllsemus,
Prof. Cope rightly considered it allied to the Mugilidae. Dr.
Zittel* placed it in the "Familie. Mugiliformes. Harder'';
but Mugilifor#aes is a group of higher than family rank and
practically equivalent to the suborder Percesoces, since it
♦Handbuch der Paleeontologie, Vol. Ill, p. 312.
26
Colorado College Studies.
was made to include the type-genera of the families Sphyrae-
nidae, Mugilidae and Atherinidae.
In studying the Cretaceous teleosts in the collection of
the University of Kansas, Mr. Alban Stewart* has recently
treated Syllaemus under the Mugilidae, but adds that its posi¬
tion in that family is very doubtful. The present writer
believes that Syllaemus, though presenting relationships to
the Mugilidae, can not be referred to that family, and should
be made the type of a distinct family, Syllaemidae, differing
from the Mugilidae and resembling the Sphyraenidae in hav¬
ing the body elongate and subcylindrical and the head long,
pointed and pike-like, and in the presence of a lateral line,
the latter extending along the middle of the sides; differing
from the Mugilidae and resembling the Atherinidae in having
the vertebrae considerably more than 24; differing from the
usual condition in the suborder Percesoces by the subin-
ferior position of the pectoral fins, and from that in the order
Acanthopteri by the relatively posterior abdominal position
of the ventrals, and apparently by having the anterior part
only of the mouth border formed by the premaxillary.
Genus SYLL^MUS.
Syllc^mus Cope. Report U. S. Geological Survey of the Territories,
Vol. II, p. 180; 1875. Stewart, University Geological Survey of Kansas,
Vol. VI, p. 383.
Type, Syllcemus laiifrons Cope.
Body subcylindrical or fusiform, not compressed; skull
depressed, flattish-convex above from right to left, broad
across the occipital region, in advance of which it is some¬
what contracted and produced to form a bill-like muzzle,
tapering to a narrow, truncate extremity; cranial bones, for
the most part, of subtriangular outlines as seen from above,
those on the occipital region short, those of the muzzle elon¬
gate; inferior side of head contracted, the coracoid bones
forming a keel and the lower borders of the dentaries and
also those of the large opercular bones meeting at the infero-
median line; mouth-cleft long, extending to two-thirds of the
♦University Geological Survey of Kansas, Vol. VI, p. 383.
Teleosts from Russell Substage.
27
distance from tip of muzzle to occiput; maxillaries appar¬
ently toothless; premaxillaries armed with very small conical
teeth; orbits large; vertebrae about 36 in number; dorsal fin
having a long basis, consisting of an anterior triangular,
more elevated, closely rayed lobe, which is at least for the most
part soft-rayed, having not more than three or four of the
anterior rays simple and regardable as slender spines, and of
a posterior less elevated lobe in which the rays are few,
widely interspaced, and much shorter and slenderer than
those of the anterior lobe, the anterior and posterior lobes
being connected by a portion in which the rays are obsoles¬
cent; pectoral fins subinferior, consisting of numerous small
rays; pelvic fins abdominal, placed posterior to the front lobe
of the dorsal; anal fin with short basis, its rays articulated
and distally dissected, except the first, which is simple;
caudal fin deeply forked; scales cycloid; lateral line extend¬
ing along the middle of the sides.
syll.emus latifrons Cope.
Plate I, figs. 1-6.
Syllcenms latifrons Cope. Report (Hayden) U. S. Geological Sur¬
vey of the Territories, Vol. II, pp. 181 and 273; 1875. Report (Wheeler)
U. S. Geographical Surveys West of the One Hundredth Meridiap, Vol.
IV, Ft. II, p. 27, Plate XXIII, figs. 1, la; 1877. Stewart, University
Geological Survey of Kansas, Vol. VI, p. 384, Plate LXXII, fig. 2; 1900.
Body relatively stout in the anterior and middle region,
broadest a little in advance of the middle. The rostrum,
viewed from above, has the form of an elevated, apically
truncated isosceles triangle. As to length of basis, the dorsal
fin equals at least nearly a fourth of the total length of the
fish, and has the posterior rayed lobe about equal to the an¬
terior, the subrayless interval being somewhat less extended
than either lobe. .There are about 13 or 14 rays in the an¬
terior and at least 7 in the posterior lobe, those of the latter
lobe being placed (in the Lincoln county specimen) at inter¬
vals of about*5 mm. All but the anterior three or four of
the rays of the anterior lobe are distally dissected, and all
except the rudimentary first are cleft at base, each embracing
28
CoLOKADo College Studies.
the posterior part of the ray in front of it by the basal cleft.
Pectoral fin composed of 15 to 20 small rays which are
strongly bent at the proximal ends. Caudal fin strongly and
deeply forked, though much less widely so than in either of
the species of Pelecorapis herein described, the lobes very
long and narrow, the lower a little longer than the upper.
The scales are large and moderately thick, subrhomboidal,
their vertical extent about twice the longitudinal, smooth or
exhibiting only delicate concentric line-sculpture, and are
arranged in 13 longitudinal rows on either side, the lateral
line occupying the eighth row below the dorsal fin. The in¬
termediate verterbrfe are nearly as deep as long.
Measurements.—Those of the specimen studied by the
writer are: total length about 370; length of skull, measured
along median line to posterior limit of roof, 64; length of
head to posterior limits of opercular apparatus 82; tip of
snout to caudal peduncle 285; tip of snout to anterior limit
of dorsal basis 123; same to posterior preserved limit of dor¬
sal 220; same to anterior insertion of anal fin about 250;
length of longest ray of anterior lobe of dorsal about 34;
greatest breadth of base of dorsal between exteriors of the
right and left integumental grooves (being that of the anterior
lobe) 4.5; average length of verterbrfe in mid-region about 7;
height of scales on middle-posterior region about 9 mm.
Occurrence.—The example studied by the writer is from
the Benton stage of the Platte series, in the "Fencepost
limestone" of the Russell substage, near Lincoln Center,
Kansas. Professor Cope's example was given him as hailing
from the "Summit of Pike's Peak"; but as that is granite, the
Professor deemed the specimen more likely to have been
derived "from the Cretaceous or possibly Jurassic beds" at
the foot of the peak. Later, he ascribed it to the Niobrara
or Fort Pierre ("Cretaceous No. 3 or 4, of Colorado"); and
still later, he cites an, early, verbally expressed opinion of
his, that it was "probably of the Niobrara", adding that
"more full information leads to the belief that it was obtained
from some point in New Mexico."*
♦ ttee above cited Report of Hayden Survey^ pp. 181, 182 and 273; and that of the
Wheeler Survey, p. 28.
Teleosts from Russell Substage.
29
In his table of stratigraphic range of genera, page 386 of
University Survey VI, Mr. Stewart, apparently intending to
use one of the above cited statements of Prof. Cope, and in¬
advertently substituting and for or in the latter's expression
"Cretaceous No. 3 or 4", gives the range of Syllsemus as
Niobrara and Fort Pierre; but on page 384 he states that the
two specimens in the Kansas University collection are "from
the Fort Benton Cretaceous, the exact locality of which is
unknown". There seems to be no satisfactory evidence that
Syllcemus latifrons has hitherto been found except in the
Benton stage.
Remarks.—All of the above stated characters that have
not been previously recorded by Cope or Stewart (also not a
few of those that have) are indicated by the Bradbury speci¬
men. The latter, though the torsus is somewhat flattened by
pressure, so as to appear considerably wider than deep, is in
a condition of preservation exceptionally favorable to show¬
ing a large number of characters. The head and the caudal
fln are preserved practically entire. The greater part of the
inferior surface, all of the left side, and half (at the front,
all) of the superior surface are exposed, though the scales
and lateral line are indicated only by their imprints, and
these well defined on only a part of the posterior region, sev¬
eral scale-prints also appearing at one point on the nape.
The nature of the dorsal fin is shown by the double inser¬
tions and anteriorly, some of the cleft basal remnants of the
rays and, outside of these, by the basal groove for the inser¬
tion of the integument, this groove making the complete
circuit of the fin and demonstrating the continuous character
of the latter. The matrix over this fin is broken vertically
and in such a manner as to display an imprint-elevation of
the fore-lobe, showing that all but three or four of the an-
tei'ior rays were flattened and dissected soft rays. Along the
interval separating the two lobes, the rays appear at first
glance to be lacking, but were probably present, at least as
basal rudiments, as is indicated by a number of faintly im¬
pressed insertions, intervalled about as in the posterior lobe.
The pectoral and pelvic fins have been broken away. An
30
Colorado College Studies.
imprint of the middle and distal parts of five anterior rays of
the anal fin, indicates that the spine as well as the rays fol¬
lowing? it were articulated, and preserves distally some of the
fibres of four post-spinal dissected rays. The vertebrae have
fallen to the ventral surface, the corrosion of which has dis¬
played their approximate form and size in molds. The pos¬
terior borders of the scale-prints usually present one or more
shallow, rounded emarginations.
On Plate I is given a diagram of the osteology of the
skull, based on the Bradbury specimen. Both the arrange¬
ment of the bones and their morphological interpretation as
indicated in this diagram, are to be regarded as provisional.
The more or less weathered-off and broken or scaled-off con¬
dition of the cranial bones in the Bradbury specimen, is such
that it is impossible to be sure that the arrangement indi¬
cated in the diagram is entirely correct; but it is believed to
be at least nearly so. The position of the posterior part of
the parieto-occipital suture is not satisfactorily shown on the
specimen, but the surfaces of stone which were apparently
covered with the parietals are feebly elevated, and the faintly
defined inner-posterior boundaries of these slightly raised
areas are indicated in the diagram by dotted lines, as probable
approximate limits of the parietals. The bone called par-
ethmoid should possibly be called the prefrontal. On the
other hand, a prefrontal may perhaps be included as the an¬
terior part of the bone called sphenotic. The latter bone
presents uncertain indications of being crossed by a jagged
suture just anterior to the position represented on the dia¬
gram by the letters sph. If this suture is really present, the
posterior and anterior bones into which the one here pro¬
visionally called sphenotic would so be divided, may be
respectively either sphenotic and postfrontal or postfrontal
and prefrontal.
Family PELECORAPID.^.
Type-genus, Pelecorapis Cope.
Teleosts of a generalized type, combining characters of
the families Exocoetidse, Clupeidse, Albulidm, etc.; gill-arches
Teleosts from Russell Substage.
31
5; pelvic bones distinct, presenting considerable resemblance
to those of Exoccetus, plate-like, in part concave below, bearing
an anterior spine-like process; fins large, without rigid spines
(unless in case of the dorsal, which is doubtful), subtended
by large bony scales or scutes; the dorsal fin with long basis,
placed midway of the length of the body, wholly anterior to
the pelvic fin; pectoral fin subinferior; pelvic fin abdominal
and very posterior; caudal forked; scales ctenoid; lateral line
placed high on the sides in the anterior region when present.
Genus PELECORAPIS.
Pelecorapis Cope. Report (Hayden) U. S. Geological Survey of the
Territories, Vol. II, p. 182. 1875.
Form compressed and elongate; head naked, orbit large,
jaws toothed throughout, the lower jaw projecting beyond
the upper; maxillary distinct from premaxillary, forming
lateral margin of upper jaw; premaxillary short; pelvic bones
consisting of a pair of irregular plates in contact at the
median plane chiefly by the long edges of thin wing-like ex¬
pansions; anterior process of either bone long, tapering,
acute, the two of the opposite bones convergent but not
meeting; bases of median fins subtended on either side (and
in front?) by a single row, those of the paired fins subtended
at the lower side by a patch or two- to three-fold row of im¬
bricated bony gcutes; anterior ray of fins (including anal?)
simple and, in case of the pectoral and pelvic at least, articu¬
lated; dorsal fin with moderately long basis, attaining a
moderate height in the anterior part and considerably di¬
minished in the posterior, placed wholly anterior to the
pelvic fin; the latter situated far back on the abdomen, re¬
mote from the large and long, interiorly placed pectoral;
pectoral fin intermediate in length between that of Exoccetus
and that of Albula; scales small, in numerous longitudinal
rows; lateral line high on anterior region, apparently partial,
(sometimes watiting?); vertebrm of the posterior to middle
trunk region large, those of the anterior region becoming
smaller and much shortened.
32
Colorado College Studies.
Pelecorapis vabius Cope.
Plate II, figs. 1 and 2.
Pelecorapis varius Cope. Report (Hayden) U. S. Geological Sur¬
vey of the Territories, Vol. II, p. 182. 1875.
Body rather elongate, tapered-elliptic, compressed, deep¬
est in the front-middle region near and in front of the dorsal
fin and tapering thence slowly backward to caudal peduncle;
head about 4^ in total length; muzzle not elongate; mouth-
cleft reaching to about opposite posterior border of orbit;
premaxillary extending backward a little more than half of
the distance from tip of snout to below anterior border of
orbit, apparently articulated so as to be movable with refer¬
ence to maxillary; premaxillaries and anterior portion of
dentaries armed with moderately large, recurved, intervalled
teeth, maxillaries with small and narrowly interspaced teeth;
clavicle stout; pelvis of two broad, irregular, lamelliform
bones, either of which presents toward the median plane,
along which their edges are in contact, a large thin, longi¬
tudinally oblong, interiorly concave wing, or scoop-shaped
portion, thickened posteriorly, the portion exterior to which
is subquadrangular, thicker, and in part transversely convex
on its under surface. The scoop-like portion extends con¬
siderably further backward than thd quadrangular, and from
the angle formed by the outer border of the former and the
posterior border of the latter a strong, anteroposteriorly
trending articular process springs rather abruptly down¬
ward. A portion of the bone, chiefly of the thicker quad¬
rangular portion, is produced far forward as a sharp splinter¬
like process, or spine,'the inferior surface of which is trav¬
ersed near its inner margin by a shallow groove. The spine
is directed as a radius' from the articular process, and a little
obliquely, so that the two spines of the pelvic bones slightly
converge. Dorsal fin consisting of about 20 rays, the first
one of which is apparently simple or spinous, the others dis¬
sected, the 8 or 10 anterior dissected rays being moderately
tall and strong and placed in rather close succession, while
the posterior are small and well intervalled, the change from
larger to smaller rays being apparently quite gradual. The
Teleosts from Russell Substage.
33
base of the dorsal fin is subtended on either side by an im¬
bricated series of rather large smooth bony scutes. The ex¬
posed parts of these scutes are rhomboids whose two longer
sides are directed obliquely forward and downward, as de¬
termined by the direction of the anterior scute-border, there
being one scute on either side for each dorsal ray. The
scutes slope outward and downward and their upper borders
are in contact with the dorsal rays, while the lower are nearly
on a level with the articulations between those rays and the
blade-like interneurals. It is probable that these scutes con¬
stituted a sheath into which, in life, the dorsal fin was de-
pressible. Pectoral fin elongate-triangular, reaching nearly
half way to beginning of pelvic and to a point nearly under
beginning of dorsal, composed of at least 16 rays, of which
all are articulated and all, save the first, dissected; pelvic fin
abdominal, placed well back of the middle of the torsus and
beginning about under posterior limit of dorsal, consisting
of one large simple distally articulated ray and 12 or 13 dis¬
sected soft rays; caudal fin large, strongly and widely forked;
pectoral and pelvic fins subtended (apparently on lower
side only, of insertion) by scutes similar to the dorsal ones,
those of the pectoral arranged in a partly triseriate group. A
double series of scutes, representing the fore-base of the anal
fin, begins at a distance of about one and one-fifth times the
pelvic fin-length back of the insertion of the first pelvic ray;
vertebra} upward of 50, their length and depth subequal,
gradually becoming relatively small and short in the anterior
region; intermuscular bones numerous, especially above
vertebral column; scales small, arranged in 50 or more rows,
larger anteriorly than posteriorly, (a few especially large
ones on nape?), minutely and closely concentric-striate on
the anterior (concealed) part, radiately punctate-rugose on
the exposed part, which is thickened with cementum, the
posterior border toothed; lateral line short (?), very high up
on the flank in the region anterior to the dorsal fln (where
alone it has been seen), its distance from the summit there
contained about four and a half times in the half girth of
the body.
34
Colorado College Studies.
Measurements.—Length (roughly) about two feet; height,
exclusive of fins, 121 mm.; tip of snout to insertion of pelvic
fin 351; distance between insertion of first ray of pectoral
and that of pelvic fin 190 to 195; length of basis of dorsal
about 80; length of pectoral, from insertion of first ray to tip
of fin, about 95; same of pelvic fin about 52; length of verte¬
brae in posterior and middle region of body 8.5 to 9, diminish¬
ing in cervical region to 4.5 mm. or less. There are usually
one and a half to two scales in 6 mm. in the oblique rows of
the anterior, and two and a half to four in those of the
posterior region. One completely exposed scale on the nape
has a diameter of 6 mm.
Occurrence.—Benton stage of the Platte series, in the
Fencepost limestone of the Russell substage. All of the known
specimens of this fish are from Kansas: those examined in
this study being, one from near Bazine, in the eastern part
of Ness county, one from near Lincoln Center, and one from
an unknown locality probably in or near Russell county.
The "Sibley," two miles west of which Prof. Mudge obtained
Prof. Cope's type-specimen, is the old Cloud county post-
village of Lake Sibley, near the lagoon of that name which
is a former northern meander of the Republican river, north¬
west of Concordia, the present postoffice of Sibley, Kansas,
being in Douglas county.
Remarks.—The writer secured the Bazine specimen and
that from Lincoln Center,—the former by purchase, the latter
as a gift from Mr. W. S. and Mrs. A. C. Wait,—about 1888-
1890, for the Museum of Washburn College, to which he is
indebted for the use of them. The-Russell (?) county
example was of a collection personally purchased by the
writer about 1895 from the late Mr. Martin Allen, a former
State Forester of Kansas and for many years a resident of
Hays City, interested in science and much esteemed by those
who knew him. The Allen collection is part of the large
collection purchased a few years ago by General William J.
Palmer and the Colorado Springs Company and by them
presented to the Museum of Colorado College.
Teleosts from Eussell Substage. 35
The following are the parts shown in the three specimens.
In the Bazine specimen: the body; a pectoral and a pelvic fin,
both practically complete; part of the lower lobe of the caudal
fin; an imprint of the dorsal fin; a series of scutes at origin
of the anal fin. Faint traces of part of the dorsal scutes can
be seen in this and the specimen next mentioned. In the
Lincoln Center or Wait specimen: nearly all of the head and
body; the pelvic bones, several pelvic scutes and most of a
pelvic fin; numerous intermusculars. In the Martin Allen
specimen: the entire body; in greater or less part, a dorsal
fin, a pectoral fin, and both pelvic fins, with the basal scutes
of the two former, and a pelvic bone supporting one of the
latter; the clavicle; a part of a lateral line.
Ribs, vertebrae and scales are shown more or less satis¬
factorily in all three of the specimens. In the dorsal fin, the
number of rays preserved is 19; there are doubtful indica¬
tions of one or two smaller spines in front of the one men¬
tioned, and of an additional soft ray at the posterior end.
The condition of preservation of most of the scales is such
that their ctenoid character might be overlooked on a casual
inspection. The lateral line is displayed, showing the tubes,
in but one of the specimens, and in that for only the short
distance covered by twelve consecutive scales. On this speci¬
men, its former presence is doubtfully indicated further
forward, after an interruption, on two or three scales of the
same row.
Pelecoeapis microlepiS sp. nov.
Plate II, fig. 3, and Plate III.
Represented by a specimen which includes most of the
trunk and the tail.
Much smaller than Pelecorapis varins; the body more
elongate and less deep than in that species, compressed, the
ventral line and posterior half of dorsal line indicating a
fusiform lateral profile; caudal isthmus rather contracted.
Of the dorsal fin, only about 10 of the rays are preserved;
these slender and apparently soft, representing the anterior
part of the fin, which is anteriorly placed forward of the
midway point between beginnings of pectoral and anal fins.
36
Colorado College Studies.
and is well elevated, attaining a height equal to about two-
thirds of that of the pectoral fin. The pectoral, which is
preserved entire, is subinferiorly placed, large, and if in
appressed position, would reach more than one-third of the
distance from the insertion of its anterior ray to the begin¬
ning of the anal fin; it is composed of 16 strong and slender
and of about 4 posterior short and feeble rays, of which both
the first, which is simple, and the following or dissected rays
are articulated. The pelvic fin is not preserved, nor its
position indicated. The anal fin is represented by rather a
long insertion at the front of which and preceding (or partly
embracing?) it are preserved six (more, perhaps originally)
overlapping pairs of bony scutes similar to those described
as embracing the base of the dorsal fin in Pelecorapis varius.
The caudal fin, which is large, is strongly forked, much more
widely so than that of Syllcemus latifrons, its lobes long and
narrow, lanceolate, though considerably less slender than
those of the Syllcemus. Vertebrae estimated to exceed 50; ribs
well developed. Scales ctenoid, very small, much smaller
than those of Pelecorapis varius relatively to size of body,
estimated to form about 60 longitudinal rows on either side
of the body, there being about 6 scales in 6 mm. in any of
the oblique rows on the middle of the flank, glistening, seen
under the hand-lens to be ornamented each with three or four
coarse, strongly accentuated, concentric undulations on the
anterior part and with several less pronounced, longitudinal
or subradiate grooves on the posterior part, the posterior
margins being toothed. I am unable to detect any trace of a
lateral line on the parts on which scales are preserved, but
these represent but a small portion of the surface and do not
include the region in which the lateral line is known to be
developed in Pelecorapis varius.
Measurements.—Length from insertion of anterior ray of
pectoral to extremity of tail 338; from same to beginning of
anal scutes 173; from same to point under insertion of first
(or first preserved) ray of dorsal fin about 85; maximum
height about 60; length of upper lobe of tail, measured from
caudal isthmus, about 90; its breadth, midway of same length,
Teleosts from Kussell Substage.
37
19; average length of vertebrae in mid-body 6.1 mm. (15
vertebrae included within 82 mm.)
Occurrence. — Benton stage of the Platte Cretaceous
series, in the Downs limestone ("Fencepost limestone", or
"Postrock") of the Russell substage, near Bazine, Kansas.
Remarks.—The type and only known specimen of this
species was submitted to the writer late in the eighties by
Mr. Samuel G. Sheaffer, for study and to be placed in the
Museum of Washburn College, subject to return, if called
for. It has since been recalled by Mr. Sheaffer. On the
block containing it, is carved the locality record, "T. 19, R.
22, Sec. 8," together with the name of the probable former
owner or collector, "J. C. Long." For the photograph, from
which the illustrations have been made, the writer is indebted
to the kindness of Mr. Albert A. Blackman.
The species is readily distinguished from Pelecorapis
varius, as well as from all other known teleosts of the Platte
series, by the fineness of its scales, which is such as to give
the surface of the body a seedy appearance, the exposed parts
of the scales being only about as large as flax seeds, several
of them together covering only the area of a single scale of
the varius.
EXPLANATION OF PLATES.
PLATE I.
Syllcemus latifrons Cope.
Figure 1. Provisional diagram of head, natural size, showing approxi¬
mate arrangement of the bones visible from above. (See com¬
ments on same, under Remarks on the species, page 30.) Ex¬
planation of reference letters in the figure: so, supraoccipital;
i-so, interparietal portion of supraoccipital; p, parietal; epo,
epiotic;pfo, pterotic; sph, sphenotic; /, frontal; me,* mesethmoid;
pe, parethmoid; mx, maxillary; pmx, premaxillary; op, upper
part of opercular apparatus.
Figure 2. Anterior border of premaxillaries, enlarged, showing three
of the teeth.
Figure 3. Plan of the dorsal fin, natural size.
Figure 4. Elevation of the dorsal fin, natural size; the posterior part
restored in supposed approximate outline, the anterior lobe drawn
from an imprint which is practically complete in the specimen,
lacking only a narrow zone at base.
Figure 5. A group of scale-prints, across the lateral line, natural size.
Figure 6. Caudal fin, natural size, the outline in part restored; made
from a considerable part of the fin and an imprint of most of the
remainder.
*This lettering, which refers to the median shaded bone in advance of the
frontals. has been accidentally omitted from the plate.
PLATE II.
Figure 1. Greater portion of lateral view of head of Pelecorapis varius
Cope, natural size. This and the following figure have been
drawn by Mrs. Dr. J. C. Shedd, after sketches by F. W. Cragin.
Figure 2. Inferior side of left pelvic bone of Pelecorapis varius, re¬
stored, natural size; the restoration based on a right and left in
the Wait specimen and a right in the Allen; with base of fin.
Figure 3. Scales from mid-flank of Pelecorapis microlepis, sp. nov.;
enlarged to natural size from the Blackman photograph. See
Plate III.
PLATE III.
Type-specimen of Pelecorapis microlepis, sp. nov., one-half natural
size. From a photograph by Mr. Albert A. Blackman.
[Note. —The writer takes this opportunity to make an acknowledg¬
ment, omitted by oversight from Volume VIII of the Studies.
The three figures of Sphenodiscus serpentinus in that volume
(Plate II, figs. 4 to 6) are from drawings very kindly made in 1897
by Mr. Robert T. Walker, Ph. B., of the Colorado College class
of 1900.]
Colorado College Studies.
Volume IX, Plate I.
Colorado College Studies.
Volume IX, Plate II.
Colorado College Studies. Volume IX, Plate III.
Colorado College
Studies.
VOLUME X.
PAPERS READ BEFORE THE COLORADO COLLEGE
SCIENTIFIC SOCIETY.
COLORADO SPRINGS, COLORADO.
March, 1903.
-115 ■
V/.\0
CONTENTS.
page.
(1) The Earliest Life of Milton, 1
Professor E. S. Parsons
(2) La Femme dans les Chansons de Geste [continued
from Vol. IX.], 24
Professor H. A. Smith.
(3) An Interferometer Study of Radiations in a. Mag-
)
Professor J. C. Shedd.
netic Field , 41
PRESS OF
tHE NEW ERA PRINTINQ COMPANY
LANCASTER, PA.
THE EARLIEST LIFE OF MILTON/
By Professor Edward S. ParsoSs."'^
The following life of Milton, now printed for the first
time, was found in 1889 by the Rev. Andrew Clark, LL.D.,
in a volume of Anthony "Wood's papers in the Bodleian
Library,^ but, owing to the pressure of other work, he had
no time to examine it. To his suggestion I owe the privilege
of bringing it to public notice. The manuscript consists of
five sheets (12 by 7^ in.), written on both sides, except the
last, which is three-quarters filled on one side and on the
other has only five lines of writing, carefully crossed out,
which contain a first draft of a passage in the manuscript
itself.® The handwriting is of a type not uncommon in the
latter part of the seventeenth century.* The corrections are
of such a sort as make it evident that the penman was the
composer, of the matter, or else that he was an amanuensis
who, as he wrote, corrected according to the dictation of the
one for whom he worked. It has not been possible as yet to
discover the author.® The manuscript was evidently written
^Reprinted from The English Historical Review, January, 1902.
^ Wood MS. D. 4.
' See p. 19, note 92.
* A facsimile of a page of the manuscript is given on p. 3.
' To relieve future students of this problem from unnecessary labour,
the following list is given of contemporaries of Milton, known to be
interested in him for one reason or another (with one or two others
mentioned by Aubrey), who did not write the manuscript (according
to the theory that penman and author are one) ; Aubrey, William
Joyner (suggested by the antiquary Lovedale as Wood's 'friend': see
Bliss's ed. of the Fasti, i. col. 480, note 5), Edward Phillips, Andrew
Marvell, Daniel Skinner, Cyriack Skinner, Samuel Hartlib, Henry Olden¬
burg, Nathan ^aget, M.D., Bishop Samuel Parker, Thomas Ellwood,
John Thurlow, Abraham Hill, Philip Meadows, Richard Jones (first
earl of Ranelagh), Edward Millington, Moses Pitt, Andrew Allam. The
2
Colorado College Studies.
Detween the death of Milton (1674) and the publication
of Anthony Wood's 'Fasti Oxonienses,' appended to the
'Athenae Oxonienses' (1691).
In the 'Fasti' appeared Wood's biography of Milton, the
first printed account of the poet's life. For its composition
Wood had at least three sources of information, but in the
opening sentence he speaks particularly of one.
"This year (1635) was incorporated Master of Arts John
]\Iilton; not that it appears so in the Eegister, for the reason
I have told you in the Incorporations 1629,® but from his
own mouth to my friend, who was well acquainted with, and
had from him, and from his Relations after his death, most
of this account of his life and writings following."
Literary tradition, dating back well into the seventeenth
century, asserts that his friend was John Aubrey.'' Wood
seems to confirm this tradition when, in discussing Milton's
'Body of Divinity,' he designates it as the book 'which my
friend calls "Idea Theologiae," ' the title Aubrey gives it
in his own life of IMilton,® which Wood had before him in
manuscript when he wrote the biography in question. But
it seems strange, nevertheless, that Wood should have referred
to Aubrey when the latter supplied him with less than ten
per cent, of his material, while the manuscript now under
discussion contributed about forty-five per cent.® Moreover
editor has examined the numerous facsimiles in Sotheby's Ramblings
in the Elucidation of the Autograph of Milton, the facsimile of the
Cambridge manuscript, and also, by the courtesy of the British Museum
authorities, Milton's Commonplace hook. There are great diflSculties
in the theory that the manuscript was written by an amanuensis. If
it is correct, Nathan Paget, M.D., was perhaps the author.
' The ' reason' was that the ' registrary of the university,' John
French, though ' a good scholar,' was a ' careless man,' and during his
term of office omitted to record the incorporations of the Cantabrigians,
of whom Milton was one.
' For a sketch of his relations with Wood, see Clark's Aubrey's
Brief Lives, introd.
® Ibid. ii. 71 f.
' The rest of Wood's biography is mostly made up of matter from
the autobiographical passages in Milton's prose works, a careful list of
his writings, and Wood's own interpretation of Milton's acts and of
national events.
The Earliest Life of ]\Iilton.
3
■nt^tc7 /tfoJ 7^ /re /c
rv^'^ filcLt Jul) jjhtKJO^ a fear TIC % ^erjon^ ajl} y Urjfun^\
:i-enlePKifij anJrnfimaf-fL'^n^^^^l^qvalo'Jiflio f fu' ^ameuj firafiai
//xref: PYi'crt\ jaatiicitfAt ewifHit
iicccm/JiHiiltTiq fwi ?r.<cct^7rari(ic^r{ffi!/afacx^^ct^ /fiu\i>iaj,]m.
-J!.. ti:, LJ„,Mliln \
u,th>s7,.-t,(r' '"''I
-P'-'j '}•<-'f u>n JixtrR il^Jx fcyx6 .
^fpoycf/c'r/q/er^ f>u /caj>pv bj fi^ h'c.ic/utc own inq'%2j^l.c(^qi^X S fiT'x
hccdnl-n'fcn.t^f}^^,! a mj one.) cnqairu cccjJion wuj) a^Jrfb; Tiot
clfic.) tpi,\c fpf ii^afh ^ cnfrtr uuou eMjc^ayjea at ^tfyaf flafaytL^ 9h}y J id
(icc decline th ifrSaisx in if/e^f/fx circamatanco even im ^omx idoci
on hp "ycluyn ihelfcr-lfpuaflec fufti l'iB~ah yxt5 d7>uikfffmh%
(hal flc.7'nafidlIcpuih il^.ui^Tiii/f o do tnm Tuvifdaa/itfainccoirgf
<^Jkfcrc %h 'flp//x.>/cc rcf-ur^^ff}0ay^
cLclncWioqcmcnf^ nf^ftu tjy^cit /a/ior.i tit an cfcQjnt'
a!in '^shkcJ Pot>tiJ
^'>om 9\0)nc licc Ifr^^JpAoPx oj(luchatmLt
\ a ,/^ wicraT>fry(nif)^ yPntUiee^'txJtii^ui^v /dcl.-nBtif'),
(:
\ a ' -y, I' yencrxnccyiniviin yonturneeHfyt^K'jppnuqutii /ttcL-aotu;,
()j tl7eyc;ci7i 0 {ric)iwyce<^ei,cd ivVc ni < <{ hrc utjh^fhcjfJismaj^
?ij nil'rrnnj^anonci fhJfi
^ap!if'uPooni'ct.\dfion yytf/y fhcj^aynono fdwdaii.Sqf^ffdionczApyoufjk
ffrapccpfeXuttidiowe^ hinnqyriH no dl piana.q<.itHnl pj fu }in>e_ Sinni
alcut JiJtccn vioPcVfs uiifjah. ■
Jixx lajf.j flu innc fJPiia f^yVeflocPo(hpoyofcac nJicfPi^ll
dci/ij!i(L qiotfne ypu rcfa.ic o/'liJea frK,p o ncitixt- infxViscb h ' ' '
ftpdJ al^iA^rpJoul^^i'V fj : dfavnyq 4'1 credoyc ^a^gjferJLat
jfeSBafejcs® tdncn a. leuJCjipfcc .xJ! a/ ^trff cojc anl aodcn lu'i,
(otic i/iuf'fi<^ hciPTit of
xyjr
t'lc diva If cdtncn if optfx. Gq m rn cup caff h ajd^ay k'"^- dih dv
JaUuyp Jcerc vcviV9^sfiaj^iiq d-d/catch ts^vfaf fed iic ckuJa^
ifiice iiifiki aftcriicnp ap. mc fm nc smaP part afnd SiTtdu fh
hry-.:...: / o'
f
jcyvicc 0
c ell a mp.-.
4
Colorado College Studies.
Wood follows the chronological order of this manuscript, and
very often its exact phraseology. IMay it not have been that
Wood meant by his 'friend' the writer of the manuscript,
but that, using his two main authorities together, he con¬
fused them for the moment when speaking of the 'Body of
Divinity' ?
The manuscript is certainly not the work cf Aubrey, for
neither the handwriting nor the style is his. He may perhaps
have secured it from some friend for Wood, but this seems
unlikely, because Aubrey himself made no use of it, although
it contains information concerning long periods of Milton's
life which Aubrey passes over almost in silence.
The autobiographical suggestions in the manuscript are
few, but some traits of its author are more or less distinct.
He was probably of Milton's own generation, an older man
than Anthony Wood. He writes as one who had passed
through the civil struggles, in which he was evidently an
Independent, though one of Milton's type, sympathising
deeply with real liberty but despising its counterfeit, be¬
lieving that some of the puritan leaders had been 'abusers of
that specious name.'^" He was a well-educated though not
altogether scholarly man, with good, though not carefully
practised, literary ability. He was probably not a clergyman;
perhaps he was a physician. He was either himself one of
Milton's friends or he was well acquainted with seme who
stood in close relations with the poet. He writes under the
impulse of a deep personal interest in his subject, and Wood
almost implicitly trusts his authority.^^
But whoever was its author, the biography is worthy of
most careful study. It affords an illuminating glimpse into
Wood's editorial methods. The way in which he uses the
" See p. 19.
" If Nathan Paget, M.D., is the author, the manuscript has a pecu¬
liar interpretative value. Dr. Paget was Milton's friend, perhaps, as
early as 1640, and was his physician during the latter part of the poet's
life. It was at Dr. Paget's suggestion that Milton married, as his third
wife, Elizahetn Minshull, the doctor's cousin. The appointment of Dr.
Paget in 1650 to the position of physician to the Tower is evidence as
to his puritan sympathies.
The Earliest Life of Milton.
5
manuscript, sometimes quoting it verbatim, then again quali¬
fying its assertions, omitting some passages and adding others
of his own composition to make an impression opposite to
that produced by the manuscript itself, is highly entertaining.
But, more than this, the manuscript throws light upon several
interesting questions in Milton's biography. It adds confir¬
mation to the theory of Joseph Hunter and Professor Masson
that the poet's grandfather lived at Stanton St. John, in
Oxfordshire—a conjecture which was proved to be correct by
Hyde Clarke's examination of the records of the Scriveners'
Company. By stating the amount of Richard Milton's in¬
come the manuscript makes it evident how he could pay the
excessive fines imposed upon him for recusancy. The manu¬
script is closely related to Richardson's life of Milton. It
confirms Richardson's report of Milton's relations with Sir
William Davenant, and mentions, what Richardson also re¬
ports, the request of the government of Charles II that Mil¬
ton should become its Latin secretary, as he had been Crom¬
well's. Moreover the manuscript has the double distinction
of being, first, the earliest biography of Milton ever, written,^^
and, secondly, the one seventeenth-century biography of the
poet in which he is treated with entire sympathy.
Edward S. Parsons.
The Life of Mr^' John Milton.
To write the Lives of Single Persons is then a commend¬
able Undertaking, when by it some Moral benefit is design'd
to Mankind. Hee who has that in aim, will not imploy his
time or Pen, to record the history of bad men, how successful
or great soever, they may have bin; unless by relating thir
Tragical ends (which, through the just Judgment of the
Almighty, most commonly overtakes them) or by discrim¬
inating, with a due note of Infamy, whatever is criminal in
thir actions, hee warn the Reader to flee thir example.
" Aubrey's Sife of Milton (in the Brief Lives), even if written
earlier, cannot be strictly called a biography; it is merely a collection
of biographical jottings.
"The title is alv ays used when the poet's name is mentioned in
the manuscript.
6
Colorado College Studies.
But to celebrate, whether the Guifts or Graces, the natural
Endowments, or acquir'd laudable Hahitts of Persons emi¬
nent in thir Generations, while it gives glory to God, the
hestower of all good things, and (by furnishing a Modell)
tends to the edification of our Brethren, is little less than the
duty of every Christian: Which seems acknowleg'd by the
late Supervisors of our Common Prayer when they added
to the Collect for the Church militant, a Clause commem¬
orating the Saints and Servants of God departed this life
in his Fear.
That Hee who is the subject of this discourse, made it his
endeavor to hee thought worthy of that high Character, will,
I make no doubt, appeer to the impartial Reader from the
particulars, w^'^ I shall with all sincerity relate of his life
and Works.
The learned John Milton, horn about the year sixteen
hundred and eight, is said to hee descended from an antient
Knightly Family in Buckinghamshire,^^ that gave name to
the chief place of thir abode. However that hee, his Father
was entitled to a true Nobility in the Apostle Pauls Heraldry;
having bin disinherited about ye beginning of Queen Eliza¬
beths reign^® by his Father a Romanist, who had an estate
of five hundred pound®' a yeer at Stainton St. John in Ox¬
fordshire, for reading the Bible.®® Upon this occasion he
"Revision of 1661-2.
" Wood gives Aubrey's opinion and his own when he says the poet
was ' descended from those of his name who had lived beyond all record
at Milton, near Halton and Thame, in Oxfordshire.' Phillips's statement
is: 'He is said to have been descended of an ancient family of Miltons
of Milton, near Abingdon, in Oxfordshire, where they had been a long
time seated.' Joseph Hunter discovered the record of a John de Milton
in Buckinghamshire in 1428. (Milton: a Sheaf of Gleanings, p. 6.)
" This would seem to make the life of Milton's father somewhat
longer than Professor Masson conjectures. The latter supposes he was
born about 1562 or 1563. However, the significance of about is elastic.
" See the reference to this passage, above, p. 5.
" Cf. Aubrey's ' Quaere—he found a Bible in English, in his cham¬
ber' (Clark's Audrey's Brief Lives, ii. 62).
The Earliest Life op Milton.
7
came yong to London, and beeing taken care of by a relation^®
of his a Scrivenor, bee became free of that profession; and
was so prosperous in it, and the Consortship of a prudent
virtuous Wife, as to bee able to breed up in a liberal manner,
and provide a competency for two Sons, and a Daughter:
After which, out of a moderation not usual with such as
have tasted the sweets of gain, and perhaps naturally in-
clin'd rather to a retir'd life by his addiction to Music (for
his skill in which hee stands registred among the Composers
of his time) hee gave over his trade, and went to live in
the Country.
This his eldest Son had his institution to learning both
under public, and private Masters; under whom, through
the pregnancy of his Parts, & his indefatigable industry
(sitting up constantly at his Study till midnight) hee profited
exceedingly; and early in that time wrote several grave and
religious Poems, and paraphras'd some of Davids Psalms.®®
At about eighteen yeers of age®^ hee went to Christs Col¬
lege in Cambridge; where for his diligent study, his per¬
formance of public exercises, and for choice Verses, written
on the occasions usually solemniz'd by the Universities, as
well for his yirtuous and sober life, hee was in high esteem
w*^'^ the best of his time.
After taking his degree of Master of Arts hee left the
University, and, having no design to take upon him any of
the particular learned Professions, apply'd himselfe for five
"Aubrey says, 'brought up by a friend of his; was not an appren¬
tice.' (Hyde Clarke has shown that this latter statement is incorrect.)
Phillips states that the poet's father took up the profession of a scrivener
' by the advice and assistance of an intimate friend of his, eminent in
that calling.'
" At this paragraph the dependence of Wood upon the manuscript
begins. .He transfers its phraseology to the Cambridge period and says:
' By this his indefatigable study, he profited exceedingly, wrot then
several poems, paraphras'd some of David's psalms '; and adds, using
material taken from the next paragraph of the manuscript, ' performed
the collegiate ffnd academical exercises to the admiration of all, and
was esteemed to be a vertuous and sober person.'
Wood says ' at fifteen years of age.' The poet was actually six¬
teen years and two months.
8
Colorado College Studies.
yeers, at his Fathers house in the Country, to the diligent
reading of the best Classic Authors, both Divine & Humane;
sometimes repairing to London, from hee was not farr
distant, for learning Music and the Mathematics.''®
Beeing now become Master of what useful knowledge was
to bee had in Books, and competently skill'd amongst others,
in the Italian language, hee made choice of that Country to
travel into; in order to polish his Conversation, & learn to
know Men. And having receiv'd instructions how to demean
himselfe with that wise observing Nation, as well as how to
shape his Journy, from S" Henry "VVotton, whose esteem of
him appeers in an elegant letter to him upon that Subject,
hee took his way®® through France. In this®* Kingdom,®®
the manners & Genius of which hee had in no admiration, hee
made small stay, nor contracted any Acquaintance; save that,
with the recommendation of Lord Scudamore,®® our®® Kings
Ambassador at Paris, hee waited on Hugo Grotius, who was
there under that Character from the Crown of Sweden.
Hasting to Italy by the way of Nice, & passing through
Genua Lighorn & Pisa hee arriv'd at Florence. Here hee
liv'd®® two months in familiar & elegant conversation with
the choice Witts of that Citty and was admitted by them to
their private Academies; an Oeconomy much practis'd among
the Virtuosi of those parts, for the communication of Polite
literature, as well as for the cementing of friendships. The
reputation hee had with them they express'd in several Com¬
mendatory Verses, w®'' are extant in his book of Poems.®®
The manuscript and Wood draw their material for this and suc¬
ceeding paragraphs covering the period of travel from Milton's Defensio
Secunda, but Wood very often adopts the phraseology of the manuscript
in preference to Milton's own words.
" Substituted for ' Journy.'
Substituted for ' wch.'
" ' hee made no stay, having ' crossed out.
"' hee waited ' crossed out.
" Perhaps it may be inferred from this that the writer had lived in
the time of Charles I.
® Substituted for ' pass'd.'
"The manuscript here closely follows the Defensio Secunda-, Wood
follows the manusfeript.
The Earliest Life of Milton.
9
From Florence hee went to Rome, where, as in all places,
hee spent his time in the choicest company; and amongst
others there, in that of Lucas Holstein.®"
At Naples, which was his next remove, hee became ac¬
quainted w*^"^ Marquis IManso, a learned Person, and so aged
as to have bin Contemporary and intimate w**^ Torquato
Tasso, the famous Italian Heroic. This Nobleman oblig'd
him by very particular civilities, accompanying him to see
the rarities of the place, and paying him Visitts at his lodging;
Also sent him the testimony of a great esteem in this Distich
Ut Mens, Forma, Decor Facies, Mos, si Pietas sic,
Non Anglus, verum herclfe Angelus ipse fores.
Yet excus'd himselfe at parting for not having bin able to
do him more honour, by reason of his resolute owning his
Religion: This hee did whensoever by any ones enquiry occa¬
sion was oflred; not otherwise forward to enter upon dis¬
courses of that Nature. Nor. did hee decline its defense in
the like circumstances even in Rome it self on his return
thether; though hee had bin advis'd by letters from som
friends to Naples, that the English Jesuits design'd to do
him mischief on that account. Before his leaving Naples
hee return'd the Marquis an®^ acknowlegement of his great
favors in an elegant Copy of Verses entitl'd Mansus w'^^ is
extant amongst his other latin Poems.®^
From Rome hee revisited Florence for the sake of his
charming friends there; and then proceeded to Venice where
he shipp'd what books he had bought®® & through the de¬
licious®^ country of Lombardy, and over the Alps to Geneva,
" Following the name, but crossed out, is ' Library Keeper at the
Vatican.' A letter above the line and before ' Library' refers to the
margin, where are the words, also crossed out, ' For I am not certain
that be was the library keeper.' tHolstein was the pope's librarian
from 1636 to 1661.]
" Substituted for ' a large.'
" The last part of the sentence originally read ' an elegant Poem
wch is amongst bis other latin Verses.' Wood borrows most of this
paragraph verbatim.
" The clause ' where . . . bought' is inserted above the line.
" Substituted for ' pleasant.'
10
Colorado College Studies.
where hee liv'd in familiar conversation with the famous
Diodati. Thence through France hee returnd home, having,
with no ill management of his time, spent about fifteen
moneths abroad.
Hee had by this time laid in a large stock of knowlege,
which as he design'd not for the purchase of Wealth, so
neither intended hee®® it, as a Misers hoard, to ly useless:
Having therefore®* taken a house, to bee®' at full ease and
quiet, & gotten his books about him, hee sett himselfe upon
Compositions, tending either to the public benefit of I\Ian-
kind, and especially his Countrymen, or to the advancement
of the Commonwealth of Learning. And his first labours
were very happily dedicated to, what had the chiefest place
in his affections, and had bin no small part of his Study, the
service of Keligion.®®
It was now the Year. IGIO: And the Nation was much
divided upon the Controversies about Church Government,
between the Prelatical party, and the Dissenters, or, as they
were commonly then calld, Puritans. Hee had study'd Ee-
ligion in the Bible and the best Authors, had^ strictly liv'd
up to it's®® Eules, and had no temporal concern depending
upon any Hierarchy, to render him suspected, either to him¬
selfe, or others, as one that writt for Interest; and therefore*®
with great boldness, & Zeal offer'd his Judgment," first in
" ' that' crossed out.
"' gotten his Books about him ' crossed out.
" ' full' crossed out.
Most of this paragraph is omitted by Wood.
" Usually the apostrophe is not nsed in the manuscript, except to
mark elision.
" Substituted for ' thence.'
" This passage is too eulogistic of Milton for Wood. He drops out
the praises and inserts at the beginning a long section discussing Mil¬
ton's relation to the struggle. A part of it is worth quoting as showing
Wood's attitude towards Milton's political views. 'Taking part with
the Independents, he became a great Antimonarchist, a bitter enemy to
K. Ch. I, and at length arrived to that monstrous and unparallel'd
height of profligate impudence, as in print to justify the most execrable
Murder of him the best of Kings . . . we find him a Commonwealths
The Earliest Life of Milton.
11
two Books of Reformation*"^ by way of address to a friend,
And then in answer to a Bishop hee writt of Prelatical Epis¬
copacy and The Reason of Church Governm*. After that*'
Animadversions upon the Remonstrants defence (the work
of Bishop Hall) against Smectymnyus** and Apology for
those Animadversions.
In this while, his manner of Settlement fitting him for
the reception of a Wife, hee in a moneths time (according
to his practice of not wasting that precious Talent) courted,
marryed, and brought home from Forresthall*' near Oxford
a Daughter of Powell. But shee, that was very Yong, &
had bin bred in a family of plenty and freedom, being not
well pleas'd with his reserv'd manner of life, within a few
days left him, and went back*' into the Country with her
Mother: Nor though hee sent sever all pressing invitations
could hee prevayl w^"* her to return, till about foure yeers
after, when Oxford was surrendr'd (the nighness of her.
Fathers house to that Garrison having for the most part of
the meantime hindred any communication between them)
shee of her own accord came, & submitted to him; pleading
that her Mother had bin the inciter of her, to that froward-
ness.*'' Hee in the Interval,*' who had entred into that
man, a hater of all things that looked towards a single person, a great
reproacher of the Universities, scholastical degrees, decency, and uni¬
formity in the Church.'
"'And then' crossea out.
"Substituted for 'After that for a first and second.'
"Wood has: 'Animadversions upon, the Remonstrants defence
against Smeotymnuus. Lond. 1641. qu. Which Rem. defence was
written (as 'tis said) by Dr. Jos. Hall, Bishop of Exeter.'
"An error for Forest-hill; a mistake, as Mr. F. Madan of the
Bodleian Library suggests, not likely to have been made by an Oxford
man.
" ' Went back ' substituted for ' return'd.'
" Wood's use of this passage is a good example ot the literal way
in which he borrowed much of the manuscript. ' It mus: now be known,'
Wood says, ' tUat after his settlement, upon his return from his Travels,
he in a month's time courted, married, and brought home to his house
in London a Wife from Forsthill lying between Halton and Oxford,
named Mary the Daughter of Mr. Powell of that place Gent. But
12
Colorado College Studes.
State for the end design'd by God & Nature, and was then
in the full vigor of his Manhood, could ill bear the disap¬
pointment bee mett with by her obstinate absenting: And
therefore thought upon a Divorce, that bee might be free to
marry another.; concerning which bee also was in treaty. The
lawfulness and expedience of this, duly regulat in order to
all those purposes, for which Marriage was at first instituted;
had upon full consideration & reading good Authors bin
formetly his Opinion: And the necessity of justifying him-
selfe now concurring with the opportunity, acceptable to
him, of instructing others in a point of so great concern*® to
the peace and preservation of Families; and so likely to
prevent temptations as well as mischiefs,®" bee first writt
The Doctrine and Discipline of Divorce, then Colasterion,
and after Tetrachordon:^^ In these®® bee taught the right
use and design of Marriage; then the Original & practise of
Divorces amongst the Jews, and®" show'd that our Savior,
in those foure places of the Evangelists,®* meant not the
she, who was very young, and had been bred in a family of plenty and
freedom, being not well pleased with her Husband's retired manner of
life, did shortly after leave him and went back in the Country with
her Mother. Whereupon, tho he sent divers pressing invitations, yet
he could not prevail with her to come back, till about four years after
when the Garrison of Oxon was surrendered (the nighness of her
Father's house to which having for the most part of the meantime
hindered any communication between them) she of her own accord re¬
turned and submitted to him, pleading that her Mother had been the
chief promoter of her frowardness.'
® ' in the Interval' read originally ' in this meantime.' ' Interval'
was substituted for ' meantime,' and ' this' changed to ' the.'
" * of so great concern ' substituted for ' so necessary.'
"' as well as mischiefs ' substituted for ' to Sin.'
" Wood changes the order of the last two pamphlets; the two were
in fact published the same day, March 4, 1644-5.
" Substituted for ' which.'
"' by expounding after other correct [ ? the word is illegible] di¬
vines the foure passages in the Evangelists' obliterated and * show'd'
substituted.
" It is not likely that a clergyman would be ignorant that three of
the ' foure places ' were outside the Evangelists. Milton discusses (1)
Genesis i. 27, 28, with ii. 18, 23, 24; (2) Deut. xxiv. 1, 2; (3) Matt.
V. 31, 32, with xix. 3-11; (4) 1 Cor. vii. 10-16.
The Earliest Life op Milton.
13
abrogating but rectifying the abuses of it;^® rendring to that
purpose another Sense of the word Fornication (and is
also the Opinion amongst others of M"" Selden in his Uxor
Hebraea) then what is commonly received. Martin Bucers
Judgment in this matter hee likewise translated into English.
The Assembly of Divines then sitting at "Westminster, though
formerly obliged by his learned Pen in the defense of Smec-
tymnyus, and other thir controversies'® with the Bishops,
now impatient of having the Clergies" Jurisdiction, as they
reckoned'® it, invaded, instead of answering, or disproving
what those books'® had asserted, caus'd him to be summon'd®"
for them before the Lords. But that house, whether, approv¬
ing®^ the Doctrine, or not favoring his Accusers, soon dis¬
miss'd him.®®
This was the mending of a decay in the Superstructure,
and had for object onely the well beeing of private Persons,
or at most of Families; His small Treatise of Education,
address'd to M*" Hartlib, was the laying a Foundation also
of Public Weale: In it hee prescrib'd an easy & delightful
method for training up Gentry in such a manner to all sorts
of Literature, as that they might at the same time by like
degrees advance in Virtue, and Abilities to serve their Coun¬
try; subjoyning directions for their attayning other neces¬
sary, or. Ornamental accomplishments: And it seem'd hee
design'd in some measure to put this in practise. Hee had
from his first settling taken care of instructing his two
Nephews by his Sister Phillips, and, as it happen'd, the Sonn
of some friend: Now hee took a large house, where the Earle
of Barrimore, sent by his Aunt the Lady Eanalagh, Thomas
" ' among the Jews ' crossed out.
" The phrase ' other thir controversies ' is quoted verbatim by Wood.
" Originally written ' the Jurisdiction '; ' the' was changed to
' their,' and finally ' the Clergies ' substituted.
® Substituted for ' term'd.'
' Those books ' substituted for ' he.'
" 'Caus'd®. . . summon'd' substituted for ' summon'd him.'
" Substituted for ' not disliking.'
Wood quotes this passage almost verbatim, as he does the next
section after the words ' Public Weale.'
14
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Gardiner of Essex, and others were under his Tuition;®^ But
whether it were that the tempers of our Gentry would not
beare the strictness of his Discipline, or for what other reason,
hee continued that Course but a while.
His next public work, and which seem'd to bee his par¬
ticular Province, who was so jealous in promoting Knowledge,
was Areopagitica, written in manner of an Oration, to vindi¬
cate the freedom of the Press from the Tyranny of Licensers;
Who either inslav'd to the Dictates of those that put them
into Office, or prejudic'd by thir own Ignorance,®^ are wont to
hinder ye comming out of any thing®® which is not consonant
to the common r.eceiv'd Opinions, and by that means deprive
the public of the benefit of many usefull labours.
Hitherto all his Writings had for subject the propagation
of Keligion or®® Learning, or the bettering some more private
concerns of Mankind: In Political matters hee had pnblish'd
nothing.®^ And it was now the time of the King's coming
upon his Trj-al, when some of the Presbiterian JMinisters,
out of malignity to the Independent Party,®® who had sup¬
planted them, more than from any principles of Loyalty, as¬
serted clamorously in their Sermons & Writings the Privilege
of Kings from all accountableness. Or (to speak in the Lan-
Wood's rearrangement and punctuation of the sentence that he
borrows from the manuscript here, as Professor Masson points out (Life
of Milton, iii. 658), obscures the meaning: 'And to this end that he
might put it in practice, he took a larger house, where the Earle of
Barrimore sent by his Aunt the Lady Ratinelagh, Sir Thomas Gardiner
of Essex, to be there with others (besides his two Nephews) under his
Tuition.' The manuscript makes it clear that Sir Thomas Gardiner
was one of Milton's pupils, as Professor Masson believes.
" Wood groups tnese suggestions under the phrase ' for several
reasons.'
' new or ' crossed out.
Substituted for ' and.'
Wood carelessly writes, ' Hitherto we find him only to have pub¬
lished political things.'
® Wood varies this, ' which he took to be only their malignity
against the Independents,' &c.
The Earliest Life of Milton.
15
guage of this"" time) Non-resistance & Passive Obedience to
bee the Doctrine of all the Eeformed Churches. This gen¬
eral Thesis, which incourag'd all manner, of Tyranny,^" he
opposed by good Arguments, and the Authorities of several
eminently learned Protestants in a Book titled The Tenure
of Kings, but without any particular application to the dis¬
pute then on foot in this Nation.
Upon the change of Government which succeeded the
King's death hee was, without any seeking of his, by the
means of a private Acquaintance, who was a member of the
new Council of State, chosen Latin Secretary. In this public
Station his abilities & the acuteness of his parts, which had
lyen hid in his privacy, were soon taken notice of, and hee
was pitch'd upon to elude the Artifice'^ of 'Eikojv
This hee had no sooner perform'd answerably to the expec¬
tation from his Witt & Pen, in 'EiKovoKXdzri<:, but another Ad¬
venture expected him.''®
Salmasius a Professor in Holland, who had in a large
Treatise, not long before, maintain'd the parity of Church
Governors against Episcopacy, put out Defensio Caroli Regis,
and in it, amongst other absurdities, justify'd (as indeed
it was unavoidable in the defense of that Cause, which was
'• Wood changes the word ' this' to ' that,' perhaps because the
doctrine became antiquated with the Revolution of 1688. The manu¬
script is certainly accurate for the time it is written, as the doctrine
was most prominent during the latter part of the reign of Charles II
and during the reign of James II.
Wood's version is, ' which as he conceiv'd did encourage all man¬
ner of Tyranny.'
"Wood's version, 'the artifice (so it was then by the Faction
called).'
" The Greek words are thus pointed in the manuscript.
"Wood's version, 'Whereupon he soon after published . . . Icono-
clastes . . . which being published to the horror of all sober men, nay
even to the Presbyterians, yet by the then dominant party it was es¬
teemed an excellent piece, & perform'd answerably to the expectation
of his Wit and Pen.' Wood goes on to state the effect the book had
on Milton's portion in the eyes of the crown at the Restoration, and
the fact that, in company with a volume by John Goodwin, it was
called in by proclamation in 1660.
16
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styl'd Belhim Episcopale) to the contradiction of his former
Book, the pretensions of the Bishops.^* Him Mr. Milton by
the order of his Masters answered in^® Defensio pro papula
Anglicano both in more correct Latin, to the shame of the
others Grammership, and by much better reasoning. For
Salmasius beeing a Forrainer, & grossly ignorant of our Laws
& Constitution (which in all Nations are the respective dis¬
tinguishing Principles of Government) either brought no
arguments from thence, or such onely (and by him not sel¬
dom mistaken or misapply'd) as were partially suggested to
him by those whose cause he had undertaken; and which,
having^' during the many yeers of our divisions been often
ventilated, receiv'd an easy solution. Nor had hee given
proof of deeper learning in that which is properly call'd
Politics, while hee made use of trite Instances, as that of the
Government of Bees, & such like to prove the preeminency
of Monarchy: and all along so confounded it with Tyranny
(as also hee did the Episcopal with the Papal Government)
that hee might better have pass'd for a Defender of the grand
Signer, and the Council of Trent, then of a lawful King and
a Reformed Church. For this and reneging his former Prin¬
ciples hee was by M"" Milton facetiously expos'd: Nor did
he ever reply, though hee liv'd three years after.''®
But what he wisely declin'd, the further provoking such
an Adversary, or persisting to defend a Cause hee so ill under¬
stood, was attempted in Clamor Begij Sanguinis &c: in which
" Wood tones down this passage, omitting some of the matter
derogatory to Salmasius, and finishing with 'wherein (in the Defensio)
he justified several matters, as Milton conceived, to the contradiction
of his former book.'
" Substituted for ' by.'
"The manuscript usually gives the words of Latin titles in the
English order.
" ' been Ven,' crossed out.
" A posthumous reply by Salmasius appeared in 1660, seven years
after his death. Wood omits almost all of this paragraph after the
name of Milton's book (the Defensio), and inserts a passage giving
facts about the burning of the pamphlet at Toulouse, its seizure at the
Eestoration, and the attacks upon Salmasius in the Mercurius Politicus.
The Earliest Life of Milton.
17
Salmasius was hugely extoll'd, and M"" Milton as falsly de-
fam'd.''® The Anonymous Author, M' Milton, who had hy
his last book gain'd great esteem and many friends among
the Learned abroad, by whom, and by the public Ministers
comming hether bee was often visited, soon discover.'d to bee
Morus, formerly a Professor & Minister at Geneva, then living
in Holland. Him, in Secunda Defensio pro populo Anglicano
he render'd ridiculous for his trivial and weak Treatise under
so Tragical a title, conteyning little of Argument, which had
not before suffr'd with Salmasius. And because it consisted
most of Railing & false Reproches, bee, in no unpleasant man¬
ner, from very good testimonies retorted upon him the true his¬
tory of his notorious Impurities, both at Geneva, and Leyden.
Himselfe bee also, by giving a particular ingenuous account
of his whole life Vindicated from those scurrilous aspersions,
with which that Book had indevor.'d to blemish him:®® Add¬
ing perhaps thereby also reputation to the cause bee defended,
at least, with impartial Readers, when they should reflect
upon the different qualiflcations of the respective Champions.
And when Morus afterwards strove to deer himselfe of bee-
ing the Author, and to represent M"" Milton as an injurious
Defamer in that particular, bee in Defensio pro se by very
good testimonies, and other circumstantial proofs justify'd
his having flxd it there, and made good sport of the others
shallow Evasions.®^
"While he was thus employ'd his Eysight totally faild him;
not through any immediat or sudden Judgment, as his Adver¬
saries insultingly affirm'd; but from a weakness which his
"Wood's version is, 'Salmasius was highly extol'd in it, and Mil¬
ton had his just Character given therein.'
" Wood uses this passage in his description of Milton's Pro se
Defensio. It belongs where the manuscript inserts it, with the Defensio
Secunda, which contains the most famous of the autobiographical pas¬
sages.
" The writer does not seem to be acquainted with the fact that the
■author of the Clamor Regit Sanguinis was Peter du Moulin, D.D., after¬
wards preben(fary of Canterbury Cathedral, who in 1670 acknowledged
the authorship of the book. Aubrey, making his notes on the life of
Milton about 1680, knew the fact; and Wood also states it.
18
Colorado College Studies.
hard nightly study in his youth had first occasion'd, and
which®" by degrees had for some time before depriv'd him
of the use of one Ey: And the Issues and Seatons, made use
of to save or retrieve that, were thought by drawing away
the Spirits, which should have supply'd the Optic Vessells,
to have hasten'd the loss of the other.®® Hee was indeed
advis'd by his Physitians of the danger, in his condition,
attending so great intentness as that work requir.'d. But
hee, who was resolute in going through with what upon good
consideration hee at any time design'd, and to whom the love
of Truth and his Country was®* dearer then all things, would
not for any danger decline thir defense.
Nor did his Darkness discourage or disable him from
prosecuting, with the help of Amanuenses,®® the former design
of his calmer Studies. And hee had now more leisure, being
dispens'd with, by having a Substitute aUowd him, and some¬
times Instructions sent home to him, from attending in his
office®® of Secretary.®^
It was now that hee began that laborious work of amassing
out of all the Classic Authors, both in Prose and Verse, a®®
Latin Thesaurus to the emendation of that done by Stephanus;
Also the composing Paradise Lost And the framing a Body
of Divinity out of the Bible: AU which, notwithstanding
the several Calamities befalling him in his fortunes, hee
finish'd after the Restoration: As also the British history
down to the Conquest, Paradise regaind, Samson Agonistes,
a Tragedy Logica & Accedence commenc'd Grammer & had
begun a Greek Thesaurus; having scarce left any part of
learning unimprov'd by him: As in Paradise lost & Regained
hee more especially taught all Virtue.
"' had ' crossed out.
" This somewhat technical discussion suggests that the author may
have been a physician. Later he gives the technical name of the trouble,
' Gutta Serena' (p. 21). Dr. Paget was probably Milton's physician
at this time.
" Substituted for ' were.'
" ' his ' crossed out.
" Substituted for ' place.'
From this and the next paragraph Wood borrows extensively.
" ' that' crossed out.
The Earliest Life op Milton.
19
In these "Works, and the instruction of some Youth or
other at the intreaty of his friends, hee in great Serenity
spent his time & expir'd no less calmly in the Yeare 1674.
He had naturally a Sharp Witt, and steddy Judgment;
which helps toward attaining Learning hee improv'd by an
indefatigable attention to his Study; and was supported in
that by a Temperance, all ways observ'd by him, but in his
Youth even with great Nicety. Yet did hee not reckon this
Talent but as intrusted with him; and therefore dedicated
all his labours to the glory of God, & some public Good;
Neither binding himselfe to any of the gainfull Professions,
nor having any worldly Interest for aim in what he taught.
Hee made no address or Court for that emploiment of Latin
Secretary, though his eminent fitness for it appeers by his
printed Letters of that time.®® And hee was so farr from
whilst in his first and second Defensio pro populo Anglicano
he was an Advocate for Liberty against Tyranny & Oppression
(which to him seem'd the case, as well by the public Declara¬
tions on the one side [and hee was a Stranger to thir private
Counsels®^] as by the Arguments on the other side, which
run mainly upon the justifying of exorbitant & lawless
power.) hee took care all along strictly to define, and persuade
to true Liberty, and especially in very solemn Perorations
at the close of those Books; where hee also, little less than
Prophetically, denounc'd the Punishments due to the abusers
of that Specious name. And as hee was not link'd to one
Party by self Interest,®® so neither was hee divided from the
Probably a reference to a pirated edition of Milton's State Letters,
printed in 1676; or perhaps to the volume of Familiar Letters (Epis-
tolarum Familiarum Liber Unus), printed in 1674.
beeing concern'd in the corrupt designs of his Masters,®® that
" There is evident sympathy here with the attitude which Milton
took towards the puritan government in its later days, with the mood
in which he wrote A Ready a/nd Easy Way to establish a Free Common¬
wealth.
" An explicit statement of Milton's exclusion from the inner circle
of the puritan government.
" On the back of tbe last page are five lines of writing carefully
crossed out, which were evidently the first draft of the passage,' Perora¬
tions . . . self Interest.' They are as follows:—
20
Colorado College Studies.
other by Animosity; but was forward to do any of tbem
good Offices, when their particular. Cases afforded him ground
to appeer on thir behalf. And especially, if on the score of
Witt or Learning, they could lay claim to bis peculiar Patron¬
age. Of which were instances, among others, the Grand child
of the famous Spencer,®® a Papist suffering in his concerns
in Ireland, and S"" William Davenant when taken Prisoner,®*
for both whom he procur'd relief.®®
This his Sincerity, and disentanglement of any private
ends with his Sentiments relating to the Public, proceeded
no doubt from a higher Principle, but was in great part sup¬
ported,®* and temptations to the contrary avoided by his con¬
stant Frugality; which enahl'd him at first to live within
compass of the moderate Patrimony his Father left him, and
afterwards to hear with patience, and no discomposure®^ of
his way of living, the great losses which befell him in his For¬
tunes. Yett he was not sparing to buy good Books; of which
bee left a fair Collection; and was generous in relieving the
wants of his Friends. Of his®* Gentleness and Humanity bee
' Perorations at the close of those Books at the close of those
so fermly & denounc'd
Books where hee denounc'd little less then Prophetically the Punish-
wch due to
ments often befell the abusers of that Specious name whether by
enlarging serve
stretching it to licenciousness or by inverting it to ye corrupt ends of
Amb[ition] And as hee was not link'd to one Party by selfe.'
" A fact not mentioned elsewhere.
"An interesting confirmation of the tradition related by Jonathan
Richardson (Explanatory Notes on 'Paradise Lost,' pp. Ixxxix-xc).
Richardson says he received the information from Thomas Betterton,
through Alexander Pope, that at the Restoration, when Milton was in
danger of losing his life, ''t was Sir William Davenant obtained his
remission, in return for his ovra life procured by Milton's interest when
himself was under condemnation, anno 1650. A life was owing to Mil¬
ton (Davenant's), and 't was paid nobly, Milton's for Davenant's at
Davenant's intercession.'
" Wood omits this and the preceding paragraph.
' by his Frugality ' crossed out.
" ' no discomposure' substituted for ' small alteration.'
" ' genero'[sity] crossed out.
The Earliest Life of Milton.
21
likewise gave signal proof in receiving home, and living in
good accord till her death with his first wife, after shee had
so obstinately absented from him: During which time, as
neither in any other Scene of his life, was hee blemish'd with
the least Unchastity.
From so Christian a Life, so great Learning, and so un-
byass'd a search after Truth it is not probable any errors in
Doctrine should spring. And therefore his Judgment in his
Body of Divinity concerning some speculative points, differ¬
ing perhaps from that commonly receivd, (and which is
thought to bee the reason that never was printed®*) neither
ought rashly to bee condemned, and however himselfe not
to bee uncharitably censur'd; who by beeing a constant^®"
Champion for the liberty of Opining, expressd much Candor
towards others. But that this Age is insensible of the great
obligations it has to him, is too apparent in that hee has no
better, a Pen to celebrate his Memory.
Hee was of a moderate Stature, and well proportion'd,
of a ruddy Complexion, light brown Hair, & handsome Fea¬
tures ; save that his Eyes were none of the quickest. But his
blindness, which proceeded from a Gutta Serena,^®^ added no
further blemish to them. His deportment was sweet and
affable; and his Gate erect & Manly, bespeaking Courage and
undauntedness (or, a Nil conscire) On which account hee wore
a Sword while hee had his Sight, and was skill'd in using it.
Hee had an excellent Ear, and could bear a part both in Vocal
& Instrumental Music. His moderate Estate left him by
his Father was through his good Oeconomy sufficient to main¬
tain him. Out of his Secretary's Salary hee had sav'd two
thousand pounds, which being logd'd in the Excise, and that
Bank failing upon the Restoration, hee utterly lost,^®* Be¬
sides which, and the ceasing of his Imploiment hee had no
damage by that^®® change of Affairs.^®* For hee early sued
'• The book was not printed until 1825.
Kead originally ' so constant a.'
This suggests the physician's technical knowledge. Richardson
in 1734 gives the same name to the trouble (p. ill).
""Down to this point Wood quotes the paragraph almost verbatim.
Substituted for ' the.'
Substituted for ' Government.'
22
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out his Pardon;^"® and by means of that, when the Serjeant
of the house of Commons had officiously seisd him, was quickly
set at liberty. Hee had too at the first return of the Court
in good manners^"® left his house in Petty France, which had
a door into the Park;^"' and in all other things demeaning
himselfe peaceably, was so farr from being reckon'd disaf¬
fected, that hee was visited at his house on Bun-hill by a
Chief Officer of State, and desir'd to imploy his Pen on thir.
behalfe.^"® And when the Subject of Divorce was under con¬
sideration with the Lords, upon the account of the Lord Ross,
hee was consulted by an eminent^"® Member of that house.^^®
By the great fire in 1666 hee had a house in Bread street
burnt: w®'^ was all the Real Estate hee had. Hee rendred
his Studies and various Works more easy & pleasant by allot¬
ting them thir several portions of the day. Of these the time
friendly to the IMuses fell to his Poetry-, And hee waking
early (as is the use of temperate men) had commonly a good
Stock of Verses ready against his Amanuensis came; which
if it happened to bee later then ordinary, hee would com¬
plain, Saying hee wanted to hee The Evenings hee
likewise spent in reading some choice Poets, by way of re¬
freshment after, the days toyl, and to store his Fancy against
Morning. Besides his ordinary lectures out of the Bible and
the^^® best Commentators on the week day. That was his
sole subject on Sundays. And Davids Psalms were in esteem
Milton was set at liberty in 'December 1660. Professor Masson
conjectures that he was arrested between 13 Sept. and 6 Nov. The poet
must then have secured his pardon before the last-named date. Charles
II came to the throne in May, and the order for Milton's arrest was
issued 16 June. He was still at large 13 August (Masson, vi. 184-95).
' in good manners ' substituted for ' prudently.'
The omission of the name of the park suggests that the writer
was a Londoner.
Richardson embodied this tradition in his introduction to Ex¬
planatory Notes on Paradise Lost, p. c.; Professor Masson rejects it.
' an eminent' substituted for ' no mean.'
Wood inserts this passage earlier, in his discussion of Milton's
Divorce tracts.
A remark of Milton not found elsewhere.
Substituted for ' its.'
The Earliest Life op Milton. 23
with him above all Poetry, The Youths that hee instructed
from time to time servd him often as Amanuenses, and some
elderly persons were glad for the benefit of his learned Con¬
versation, to perform that Office.^" His first Wife dy'd a
while after his blindness seizd him, leaving him three Daugh¬
ters, that liv'd to bee Women. Hee marry'd two more,
whereof one surviv'd him. Hee dy'd in a fitt of the Gout,
but with so little pain or Emotion, that the time of his ex¬
piring was not perceiv'd by those in the room.^^* And though
hee had bin long troubl'd with that disease, insomuch that
his Knuckles were all callous, yet was hee not ever observ'd
to be very impatient. Hee had this Elogy in common with
the Patriarchs and Kings of Israel that he was gather'd
to his people for hee happen'd to bee bury'd in Cripple-
gate where about thirty yeer before hee had by chance also
interrd his Father.
Perhaps the writer was one.
Wood repeats this sentence. The interest of this part of the
narrative will he greatly enhanced if the suggestion that the writer
was the attending physician is found to be correct.
' that' crossed out.
* was gather'd to his people' substituted for ' slept with his
Fathers.'
LA FEMME DANS LES CHANSONS DE GESTE.
Br H. A. Smith.
[Continued from Vol. /X.]
IV.—L'Epouse.
Les jeunes filles sont assez souvent calomniees par les
poMes, au moins par ceux qui vinrent plus tard. Mais en
revanche ils mettent ordinairement les femmes mariees dans
une lumiere beaucoup meilleure. La position de I'epouse
etait en theorie egale a celle du mari. C'est ce qu'atteste
cette phrase de la belle Aude repetee mille fois par d'autres
femmes: "Qui jurait me prendre comme son pair."^ Mais
au XII® siecle elle n'etait pas son egale en reality.
Sous quelques rapports la femme n'etait que la vassale du
baron. Quels etaient par exemple les droits d'une epouse?
On lui nommait un douaire a son mariage mais nous ne voyons
nulle part qu'elle eut sur celui-ei des droits particuliers pen¬
dant la vie de son mari. C 'etait seulement apres sa mort que le
douaire etait a elle.^ Elle tenait un fief de la meme maniere.®
EUe etait toujours representee par son mari aux cours, et
dans les affaires si elle en avait. Ceci etait necessaire ou la
justice etait un arret d'armes.
Le seigneur feodal pouvait executer sa femme pour des
crimes, comme on voit dans Parise la Duchesse et Macaire,
ou on allait la bruler pour des crimes honteux et ou elle
etait a la fin divorcee et chassee du pays par I'arret de son
• Voy. note audessus.
2"De son doiare ne doit estre oblige" (Aymeri de Narbonne, V.
4434). " De Eibemont iert ma feme douge" (Raoul de Cambrai, V.
5737.)
' II n'y a pas d'exemples otl ime femme soit investie d'lm fief sans
lui donner en mgme temps un mari.
La Femme dans les Chansons de Geste.
25
mari.^ II est vrai que dans Macaire ce fut pour le crime
d'adultere, pour lequel I'eglise permettait une peine pareille.
Sans doute I'eglise y exer^ait une influence salutaire, mais
dans Tine societe ou la force etait le droit, on ne pouvait tou-
jours s'y fier." Le mauvais traitement des femmes est le
sujet de plusieurs chansons de geste,® et c'etait un devoir du
chevalier de redresser les torts des dames.
II ne manque pas de proverbes malins contre I'epouse,
quoiqu'on puisse les attribuer pour la plupart a la malice
des poetes, parce que les epouses qui etaient vraiment me-
chantes sont peu nombreuses.*
Cependant les femmes avaient leurs petits defauts. Par
exemple eUes n'etaient pas toujours assez discretes. Le pere
de Doon, dans ce beau passage ou il donna des conseils a son
flls, dit: "Et quant tu saras rien que celer tu vourras,—ne le
dy a ta femme nulement, ce tu I'as:—car. ce elle le scet, tu t'en
repentiras—au premier desplaisir que tu mais lui feras."®
Mais il y a aussi des sentiments contraires et avec plus de
raison. Ainsi quand Doon etait en prison il nomma toute
sa grande lignee qui I'avait oublie, mais il ajouta: "mes de
tous cbeus ne m'est vaiUant .1. oef peles,—forsque de ma
mouillier, qui tant m'avoit ames."* De plus les beros les
plus renommes n'besitent pas a prendre conseil a leurs
femmes, qui le donnent souvent tres sagement.'' Sans doute
Guillaume d'Orenge n'aurait pas ete un si grand bomme sans
1 Parise la Duchesse, V. 6013. Macaire, V. 382.
' Quand le roi avait enlevfi l'6pouse de Bernier et allait la donner a
un autre, elle dit: "Biaus sine rois, merci.—n'encor gaires que B. li hardis
—^m'a espousfie par vert6 le vos di;—^jugies en droit, li clerq de cest
pais. Que la loi Deu aveis a maintenir. Laerfis vos dent crestientfi
honir ?" Mais de peur du roi, " Trestuit se taissent li grant et li
petit" (Baoul de Cambrai, V. 6185).
' Parise la Duchesse, Doon de maience, Berte aus Grans Pi6s, Ma¬
caire etc.
* Un bourgeois prend piti6 d'Aiol et veut lui donner des habits,
mais sa femme s'y oppose et dit du mal d'Aiol. Cest un passage
auquel je n'ai gafere vu un semblable (Aiol, V. 1220).
5 Doon de Maience, V. 2471.
sGaufrey, V. 1774.
T Aymeri de Narbonne, V. 3782.
26
Colorado College Studies.
Guibor.e.^ Que le bon chevalier aimait et honarait sa femme,
niille passages nous le temoignent. Les manieres entre le
niari et Tepouse etaient des plus respectueuses. II I'appellait
toujoi;rs "ma belle soeur" ou "belle dame."^
Devaut son seigneur, c'etait le devoir de la femme d'obeir,
et il y a beaucoup de passages qui attestent son humilite meme
dans les circonstances les plus provocantes. Sa reponse
ordinaire etait "tout a votre plaisir."
L'influence des femmes sur leurs maris, souvent de moeurs
trop sauvages, est bien evidente dans une scene touchante, et
amusante en meme temps, dans Girart de Eossillon. Ce grand
fier, Girart, qui avait ete chasse de son pays par le roi, fut
exhorte par un saint hermite a renoncer a sa colere et a faire
penitence. Mais, en vrai baron du moyen age, aux plus belles
prieres il n'avait qu'une seule reponse obstinee: "Je veux
tuer le roi." Ce ne fut qu'a la priere de Berte, sa femme,
qu'il ceda.®
La vie de I'epoque devait donner a la femme une immense
influence morale. Pendant les longs bivers, le baron vivait
au sein de sa famille, et on pent croire que la femme avait
alors la meilleure pretention a I'egalite avec son mari, egalite
jamais reconnue dans les droits on dans la vie ordinaire.
Elle s'asseyait a son cote dans la salle ou a table.^ EUe avait
des servantes, qui, si elle etait duchesse ou comtesse, etaient
des jeunes filles nobles, comme les pages de son mari etaient
des fils de chevaliers.® C'etait honteux a elle de sortir seule.®
Les devoirs de la femme du baron etaient en general les
memes que nous avons donnes pour "la jeune fiUe," en ajou-
tant ceux de la maitresse d'une maison. Elle suveillait la
' Voy. la scSne devant Orenge cit^e plus loin.
2 Le titre ordinaire de la femme Stait " dame." Dans Macaire oil
la reine Blanchefleur rtait d^guis^e comme femme du boucheron, le roi
la salua comme " Commere" et aprfes qu'il eut appris sa vraie posi¬
tion, il disait toujours "dame" (Macaire, V. 1411).
3 Girart de Eossillon, V. 2207.
* Gui de Nanteuil, V. 1877.
3 Macaire, V. 58.
5 Vos estes joine dame, et tote sole alez! Se li dus le savoit vos
en sauroit malgr^ (Parise la Duchesse, V. 361).
La Femme dans les Chansons de Geste. 27
maniere de placer les invites, et quand des hotes arrivaient au
chateau la femme avec le chatelain descendait le perron pour
les recevoir.^
C'etait en I'absence du seigneur dans les guerres ou les
voyages que sa femme avait plus de soucis. Elle etait alors
maitresse du chateau et avait beaucoup de devoirs qui appar-
tenaient ordinairement au chatelain. Tons les gens de la
maison et meme les hommes de guerre etaient a ses ordres, et
on ne voit aucun poeme ou le baron se plaint de sa fidelite."
Sans doute on dira que cette vie de la femme n'etait pas
gaie, et cela est vrai. Ordinairement le chateau etait pour
elle le monde. Elle n'avait pas beaucoup d'amusements.
Comme son mari, elle jouait aux echecs, le jeu par excellence
du moyen age. Puis elle avait toujours sa broderie,® et quel-
quefois un jongleur r.ejouissait le chateau pendant deux ou
trois journees. C 'etait pour elle, comme pour tous les autres,
une fete.* Quant aux joutes pendant le douzieme siecle, nous
ne croyons pas qu'elles fussent une grande source d'amusement
comme plus tard. On ne les voit guere sauf aux celebrations
d'un mariage ou de quelque chose de semblable. La vraie
bataille etait trop frequente et trop rude au XII® siecle, pour
qu'on aimat beaucoup a imiter. la bataille, excepte comme
preparation au combat, ou pour se defaire des exuberances
de la jeunesse. A "I'adoubement" d'un chevalier ou au
mariage, il y avait toujours des exercices a I'escrime et au
"behourd," mais il ne s'agit pas de mettre en scene des dames
ou d '^changer des defis courtois. A ces joutes improvisees la
femme etait souvent prfeente, mais elle n'y jouait aucun role.
'" Li vint encontre ses genres Loeis, et la roi'ne qui moult ot cler
le vis" (Aliscans, V. 2604).
"Dame Aye d'Avignon a fet grant courtoisie: Les degrez avala,
s'a chascune baisie" (Gui de Nanteuil, V. 2928).
2 Quand les sarrasins allaient brfller Aymeri devant son chateau,
sa femme dit, "Que sain et sauf et vif le me rendez—je vos rendrai
Nerbone la cit6 (M. Aymeri de Narbonne, V. 1496). E. Branumunde
les turs li ad ^pndus " (Roland, V. 3655).
3 Voy. note sur la jeune fllle.
* Pour le vrai type du jongleur, son metier et son accueil, voy.
Huon de Bordeaux, V. 7331.
28
Colorado College Studies.
La joute eomme jeu proprement dit, est evidemment plus
recente.
Pour donner une idee plus vive de Tepouse au moyen age,
nous citerons deux ou trois incidents dans les vies de quelques
femmes les plus renommees de nos chansons de geste.
C'est Hermenjart, la femme d'Aymeri, au sujet de la-
quelle on a deja vu des scenes charmantes. Un jour le vieux
Aymeri fut blesse et fait captif par les paiens. lis le lierent
a un poteau devant Narbonne, le battirent borriblement et
menacerent de le bruler s'il ne rendait pas la ville. Mais en
vrai pere de Guillaume et de Naimer, il implora sa femme de
ne pas rendre le chateau. Ce ne fut qu'apres qu'on cut
allume le feu, que cette femme beroique qui donna tout pour
son mari, traita avec les paiens. Mais ce qu'elle fit pour
Aymeri elle ne I'aurait pas fait pour elle-meme. Plus tard
elle fut assiegee dans le donjon et elle ne se rendit point, meme
quand il ne restait que trois femmes presque mortes de famine.^
Une autre est Berte, ce type de bonne femme cbretienne
du moyen Sge. Quand son mari, Girart, fut cbasse de son
pays, elle le suivit a I'exil et par sa bonte et sa piete apaisa
la colere de ce fier guerrier. Pour gagner leur vie, cet bomme
noble, recemment comte et seigneur de la moitie de la France,
fut force a devenir cbarbonnier. et a porter son cbarbon
de bois pour le vendre dans les villes—"ciel, quel fardeau il
portait"—et Berte devint coutouriere: "Se seoit toute jour
en la poudre—et gaaignait son vivre au tailler et au coudre-
maul vestue et cbaucbiee et tout entorcbonnee-Couvroit sa
grant biaute la gente fauconnee."®
Enfin c'est Guibor.c, la femme beroique de Guillaume
d'Orenge. Quand Guillaume a livre aux paiens cette bataille
terrible d'Aliscans, ou son neveu Vivien, le Eoland de la
maison de Narbonne, meurt dans ses bras, sept des plus
grands combattants de sa famille sont pris, et ses vingt mille
Fran§ais tues jusqu' au dernier bomme; alors ce geant guer¬
rier, terrible dans son desespoir, par ses seules forces rompt
les rangs des sarrasins et s'en va a Orenge. Toute I'armee
1 Mort Aymeri de Narbonne, V. 1490.
' Girart de Rossillon, V. 2369.
La Femme dans les Chansons de Geste. 29
paienne le poursuit; mais il tue le plus brave et, habille
comme un paien, il arrive devant la ville.
Le portier, un pretre et Guiborc avec les femmes sont
les seuls habitants de la ville. Tons les hommes restent
sur le champs d'Aliseans. Epuise par ses soixante heures
de bataille, ses quinze blessures et la douleur de sa defaite,
il s'arrete a la grande porte et demande qu'on I'Guvre. Mais
le portier ne reconnait pas ce chevalier, seul, convert de sang
et arme en paien. Guiborc vient a la tour et demande son
nom. "Je suis Guillaume" dit-il en pleurant, "Les paiens
me suivent. Ouvrez la porte." "Jamais" repond cette
femme sage, "juSqu' a ce que j'aie vu votre visage." II va
oter son heaume lorsqu' un parti de sarrasins mene une troupe
de prisonniers frangais pres de la ville. "Ah" dit elle. " Je
vais voir si vous etes vraiment Guillaume. Jamais Guillaume
ne permettrait une telle indignete." II ferme son heaume
et se lance sur les paiens, qui fuient avec effroi ses coups
terribles. Alors elle ouvre la porte d'Orenge.
Mais lorsqu'elle va lui oter I'armure elle dit: "Pourquoi
est-ce que je vous ai laisse entrer? Si vous etiez Guillaume
vous seriez revenu vainqueur. Ou est,Vivien et I'armee
frangaise"? "Morts," dit le comte en pleurant, "tons sont
morts en Aliscans."
Elle se pame de douleur mais lorsqu'elle apprend que ces
sept comtes sont captifs, elle devient encore courageuse.
"Pars" lui dit-elle. "Va en France chercher de I'aide chez
le roi." Elle ne pense plus aux blessures de Guillaume, a sa
fatigue, a sa douleur. En vain il y oppose de bonnes raisons.
"Pars" dit-elle, "pars toujours. Moi et les femmes nous
garderons les murs.'' Et Guillaume part. II fait le voyage
dangereux jusqu'a la cour, et deux mois plus tard, lorsque
I'armee frangaise arrive devant les murailles d'Orenge, la
premiere chose qu 'on voit est Guiborc en armure et les femmes
qui defendent encore la ville.^ Elle avait raison de lui dire:
"Bienheureux doit etre I'homme qui a bonne femme—et s'il
est bon il I'aimera de fin coeur."^
»Aliscans,, V. 3978.
' Aliscans, V. 1597, 2035, 8408.
30
Colorado College Studies.
v.—La Mere.
Nous devons parler de la mere, mais elle est raremenl
trouvee dans les chansons de geste. Cependant les exemples
que nous en avons indiquent que la mere n'etait pas moins
veneree alors qu'elle Test aujourd'hui, qu'elle I'a ete toujours.^
II y a une question interessante et, semble-t-il difficile a
resoudre: Les meres nobles—allaitaient-elles leurs enfants?
M. Gautier dit: "II nous faut bien constater non sans quel que
regret, que les meres de nos chevaliers ne nourrissaient pas
volontiers leurs enfants, et que I'usage des nourrices etait des
lors tres repandu."^ II parle le plus souvent des moeurs
du XII® siecle.
Nous ne voulons pas dire que cette assertion ne soit pas
vraie, par.ce que nous n'avons pas toutes les preuves du con-
traire, mais nous croyons que la phrase appliquee a la femme
du XII® siecle dit trop, si I'on I'appuie seulement sur les pas¬
sages que cite M. Gautier, et aussi sur ceux que nous avons
pu trouver.
(I) D'abord il cite un passage dans Les Sept Sages, ecrit
peut-etre au XV® siecle. IMais une autorite du XY® siecle
pouvait ignorer aussi bien que nous le XII® siecle. (II) Un
autre passage cite est de Brim de la Montaigne® on la mere
dit "qu'elle n'avait pas de lait pour son enfant" et emploit
une nourrice. ]\Iais ce passage etait necessaire a I'bistoire,
pour y faire entrer la nourrice, qui etait fee et marraine de
I'enfant, et qui jouait un role capital dans la vie du dernier.
De plus, ce poeme est un roman du XY® siecle. (Ill) Dans
Gui de Nanteuil, aussi cite par. M. Gautier, le poete dit, "11
norricJiez li baillent pour lever et haignier."^ On ne dit pas
1 Dans deux po&mes oR une femme fut condamn^e R mort la peine
fut chang^e en exil parce qu'elle se declara enceinte. C'est un fait
int4ressant consid^6 en rapport avec les droits plus rficents (P. la
Duchesse, V. 616; Macaire, V. 680) : Dans le premier passage un pr6tre
accusa une femme de sa confession et R cause de eela il fut mis R mort.
C'est une confirmation frappante de la saintetS de la confession.
2 La Chevalerie, p. 118.
3 V. 1867.
* Gui de Nanteuil, V. 116.
La Femme dans les Chansons de Geste.
31
qu'elles allaitassent I'enfant, et cette phrase souleve la ques¬
tion si le mot nourrice voulait dire necessairement une femme
qui allaitait I'enfant. Nous croyons que non. Dans le pas¬
sage cite Des Sept Sages I'enfant avait "trois nourrices, I'une
le baigna, I'autre le caucJia, et I'autre I'allaita." Dans Aiol
les deux enfants jumeaux avaient quatre nourrices}
N'est-ce pas done que le mot nourrice etait evidemment
employe dans un sens plus etendu que celui d'allaiter?—
S'il n'est pas vrai, on ne pourrait eoncilier aucunement ces
vers dans Raoul de Cambrai: (IV) M. Gautier cite le vers
suivant de 1 'enfant Raoul: " Et la nourrice qui moult ot cler
le vis."^ Mais sa mere Ailis dit dans le meme poeme: "Ja
I'ai je lase si doucement norri," et aussi: "Biax fix Raoul,"
dist Ailis la bele, "je te norri del lait de ma mamele."^ II
semble ici que la nourrice etait tout bonnement la servante
qui soignait 1 'enfant.
(V) Dans Jourdains de Blaivies,^ ou il y avait deux en¬
fants, dont 1 'un n 'etait pas fils de la chatelaine, on ne dit pas
que les nourrices allaitassent I'enfant, mais c'est probable.
(VI) Dans Aiol ou il y a quatre nourrices, les enfants avaient
ete enleves et n'avaient pas de mere.®
(VII) Un des renvois est dans Godefroi de Bouillon, ou le
beros etait allaite par sa mere, ce qui fut regarde comme ex¬
ception par le poete.® (VIII) Enfin le dernier passage cite
par M. Gautier est dans Parise la Ducbesse, ou I'beroine, qui
etait en exil et privee de son propre enfant, devint nourrice
du fils d'un baron. 11 n'y a pas de doute a ce sujet. Elle
dit: "Norice serai bone, car j'ai lait assez."^ Mais ici I'bis-
toire avait besoin de cbercber une occupation pour la femme.
Le dernier passage est le seul du XII® siecle qui indique
avec certitude qu'une nourrice allaitait I'enfant quand la
' Aiol, V. 9369.
' Raoul de Cambrai, V. 86.
'V. 1147, 1001.
* Parise la Ducbesse, V. 944.
5 Jourdains de tlaivies, V. 576.
® Godefroi de Bouillon, V. 639.
'Aiol, V. 9368.
32
Colorado College Studies.
mere pouvait le faire, et on a une preuve du contraire toute
aussi forte dans Raoul de Cambrai, une des meilleures a.u-
torites.
(IX) Dans IMacaire il y a un passage on il semblerait que
la mere allaitat son enfant: "Mais la roine qui la nori souef—
Qui de sa fille connoist cuer et pense."^ Enfin on pourrait
dire beaucoup contre I'assertion que 1'usage des nourrices
etait tres repandu, en alleguant les moeurs et la condition de
la societe du XII® siecle. Mais c'est ime question qui merite
une recherche a part, et nous en avons deja trop parle pour
la portee de cette these.
La mere avait ime part importante a 1'education de I'en-
fant.^ Les premieres annees des fils etaient confiees a ses
soins. Quant aux fiUes, on n'a pas besoin de le demander.
Elles etaient confiees aux soins particuliers de leurs meres
jusqu'au mariage, et meme ton jours.
II y a une chose digne de remarque sous ce rapport. Dans
ces poemes ou les jeunes filles jouent un role si effronte, on
ne fait jamais mention d'une mere. Nous avons cherche
dans I'histoire d'une dizaine des plus mechantes heroines et il
n'y a pas un seul passage ou I'on trouve une mere. On pour¬
rait presque croire qu'eUes etaient toutes des orphelines de
mere. Mais^qu'est-ce que tout cela veut dire? C'est, nous
le croyons, que la mere aurait ete un empechement an role
qu'on donnait aux jeunes filles. Si celles-ci avaient eu des
meres, elles n'auraient pas ete si effrontees. Tout cela n'est
pas naturel et on pent bien douter de ces poetes-la.
Comme toujours une amitie la plus etroite liait ensemble
la mere et les fils. La mere etait la mediatrice entre eux et
leur pere, souvent trop emporte. Elle ne les oubliait jamais.
Dans Renaud de IMontauban® les quatre fils d'Aimon, qui
etaient poursuivis par le roi et chasses par leur pere, re-
tournerent un jour en haillons an chateau et demanderent a
manger, et pendant que la mere les servait, elle les reconnut
en depit de la longue separation. Ah! quelle joie eUe en
' Macaire, V. 1784.
2 Aiol, V. 268, deja. cite.
3 P. 89.
La Femme dans les Chansons de Geste. 33
avait! Et comme elle les chargea de vivres et d 'habits quand
lis partirent!
Le fils etait respectueux envers sa mere. II y a une setile
exception. C'est dans eette chanson des moeurs sauvages,
Eaoul de Cambrai. Ailis cherchait en vain a decider Raoul
k ne pas faire la guerre contre les fils d'Herbert. II se facha
et lui repondit brutalement,^ et dans un moment d'exaltation
elle le maudit. Mais elle s'en repentit: "Ainc en trois jors
ne menga ne dormi,—Tout por son fil qu'elle avoit laidi."^
Et apres qu'il fut tue, dans toutes les scenes sanglantes qui
suivent, on la voit de temps en temps passer, comme un spectre
perpetuel de la vengeance. II y a surtout une scene superbe.
C'est ceUe ou Bemier, meurtrier de Raoul, est porte sur un
lit, blesse presque a mort. Ailis le voit, et saisit un gros
baton pour I'assommer. Et Bernier, qu'elle avait nourri, se
traine a ses pieds en lui criant merci. C'est le coeur d'une
mere aux prises avec la pitie d'une femme.®
La mere du XII® siecle etait courageuse. S'il le fallait
elle pouvait tout sacrifier. En Daurel et Beton un traitre,
qui avait tue son seigneur, voulait s'emparer du petit fils,
heritier. du fief. L'enfant etait entre les mains d'un jongleur
et de sa femme, fidMes sujets de leur seigneur. Le traitre
attaquait leur maison et allait I'emporter. Qu'est-ce qu'ils
feront? C'est la femme qui repondit. "Donnez-lui notre
fils," dit elle, "ils sont de meme age. Notre fils mourra mais
notre seigneur sera sauve." Le brutal traitre brisa la tete
de leur enfant contre le perron. Le jongleur s'echappa sur
la mer avec le petit heritier, et la femme heroique mourut de
douleur. C'est le comble de la feodalite.*
VI.—La Veuve.
Peut-etre les veuves meritent-elles un paragraphe a part;
sans doute il y en avait assez dans ces jours de batailles et
de croisades. Leur sort certainement n'etait pas enviable.
IV. 1100. •
2V. 3512.
3 Raoul de Cambrai, V. 5243.
* Daurel et Beton, V. 1013.
34
Colorado College Studies.
Pour maintenir leur fief il leur fallait presque toujours se
remarier et quelque fois a un homme qu'elles haissaient, peut-
etre a 1 'asssassin de leurs maris qui voulait s 'emparer de leurs
fiefs.^ II semble que le parent ou le seigneur eut le meme
droit sur les veuves qu'il avait sur la jeune fiUe.® Si les
veuves n'avaient pas de fils d'un age a maintenir le fief leur
seul moyen d'echapper a un mariage desagreable, etait de
devenir religieuses et e'est ce que beaucoup faisaient.®
Cette condition sans defense des veuves est partout recon-
nue dans les chansons de geste. La principale recommanda-
tion de Charlemagne a son fils Louis fut de ne rien oter aux
veuves; * et 1 'homme qui maltraitait les veuves et les orphelins
etait type d'un homme mauvais.®
VII.—La Keligieuse.
On pourrait ecrire toute une dissertation sur la religieuse
du moyen age. Mais on ne voit pas que la femme du XII®
siecle devint volontiers religieuse sauf pour quelque cause
comme celle citee plus haut. C 'est ordinairement une femme
qui n'etait plus jeune, et qui se retirait apr^ la perte de son
mari.
Pourtant on voit assez souvent des maisons religieuses pour
les femmes.® Girart et Berte en fonderent.'' On en men-
tionne deux dans Kaoul de Cambrai.®
1 C'est ce qu'on voulut fairs en Boon de Maience et qu'on accomplit
en Daurel et Beton.
2 La femme de Bernier retourna chez son pfere et le roi la maria &
I'ennemi de Bernier (Raoul de Cambrai, V. 6790). Daurel et Beton,
V. 644.
'Hermenjart " nonain devint et servfi Damedfi" Mort Aymeri de
Narbonne). C'est la menace ordinaire d'une femme qui s'oppose a un
mariage.
* Couronnement Looys, V. 84.
®" Les orfenins faisoit desireter—Les veuves dames lor rentes re-
coper—Moult le maudient li home du ren€" (Huon de Bordeaux, V.
2465).
®Aye d'Avignon, p. 29.
' Girart de Rossillon, p. 228.
8V. 1394, 7315.
La Femme dans les Chansons de Geste.
35
VIII.—Conclusion.
Nous avons deja parle de la grande difference entre les
jeunes filles des poemes les plus anciens et celles des plus
recents. Quoiqu'il n'y ait pas beaucoup de renseignements
sur la femme dans les chansons de geste plus vieilles, le peu
qu'on trouve la met dans une lumiere tres belle. Mais dans
les poemes du XIII® siecle les jeunes filles sont souvent des
monstres d'effronterie et d'impudicite. Quelle est 1'explica¬
tion de ce changement?
M. Gautier, avec d'autres, dit que les poetes mentent tout
bonnement.^ Sans doute il a raison jusqu' a un certain point.
On ne pent pas croire les femmes aussi mechantes que quelques
trouveres les out peintes. Et quand les choses depassent toute
imagination, toute ressemblance au naturel, on pent, a juste
titre, refuser de les croire. Mais si Ton accepte leur temoign-
age en beaucoup de faits importants et quelquefois tres
etranges, peut-on en douter entierement en d'autres choses
sans en donner une explication suffisante? Et si les vieilles
chansons de geste sont vraiment un reflet de la vie de leur
temps, qu'est-ce que signifient ces caricatures de la jeune
fille du XIII® siecle et de la fin du XII® ? Parce que s 'il est
vrai qu 'elles soient principalement des caricatures et des men-
songes il doit exister une raison pour que les gens les ecoutas-
sent volontiers.
Tout en acceptant les belles raisons qu'on donne au
sujet de la malignite et de 1'ignorance des poetes a I'egard
de la femme, nous croyons que ces portraits indiquent un
changement notable dans la position de la femme et dans
les moeurs du temps. On sait que les XI® et XII® siecles
etaient la periode d'ime renaissance religieuse et morale
au nord de la France,^ la region ou I'on croit que presque
toutes les chansons de geste ont leur, origine. L'eglise
en etait la cause, et les moeurs etaient tres auster.es. Mais
au sud les conditions etaient tout-a-fait differentes. La
societe etait plfls elegante et plus libre, mais moins simple et
1 La Chevalerie, p. 377.
2 Voy. Guizot et Martin.
36
Colorado College Studies.
moins morale. On voit la les cours d'amours qui jugent
'' que 1 'amour n 'est pas possible entre des maries," et d 'autres
jugements pareils.^ Les moeurs etaient licencieuses et on
salt que plus tard, au moins pendant le XIV® et XV® sieeles,
les memes conditions arrivaient au nord, ee que temoignent
les romans souvent tres immoraux de la periode decadante,
aussi bien que les historiens. N'est-ce pas possible done
que ces portraits dans les poemes indiquent 1'influence de
la societe pen chaste du midi, qui influait de si bonne heure
sur les moeurs du nord? C'etait au XII® siecle que les croi-
sades et les diverses expeditions militaires commencerent cette
amalgame des idees, des langues et des moeurs, qui faisaient
la France unie. C'est alors que les barons rudes et guer-
riers du nord voyaient, non seulement la civilisation du midi
de 1'Europe, mais aussi le luxe et les vices de I'orient; et on
doit noter ici, nous semble-t-il, que le plus grand nombre des
heroines, qui jouent un si mauvais role dans les chansons, sont
des sarrasines on des paiennes.^ De plus il parait vrai-
semblable qu'il y ait dans plusieurs poemes des elements de
deux societes bien differentes. On ne pent guere croire
a une autre explication des deux parties d'Aiol, dont I'une
a des moeurs si austeres tandis que I'autre renferme tout
le mauvais gout, et toute I'immoralite de la periode deca¬
dante.® Le temps entre les dates de composition des deux
parties semble une explication insuffisante pour un tel change-
ment dans les moeurs. Aussi ne faut-il pas oublier qu'il y
avait des poemes auxquels il n'y a rien de tel a reprocher,
comme Aymeri de Narbonne, ecrit au XIII® siecle. lis sont
des imitations, c'est possible, mais on voit qu'il y avait un
pays on une societe ou on desirait de telles imitations.
Mais si ces portraits des jeunes fllles donnent un tableau
quelconque de la societe de I'epoque, quelle etait vraiment la
1 Le Roux de Lincy, " Les Femmes celSbres de I'ancienne France,"
p. 179.
2 Sur douze des plus m^chantes, neuf sont des palennes. Les deux
les plus abominables sont Floripas en " Fierbras," et Sebille qui est
mari^, en " La Chanson de Saisnes."
3 Aussi EHe de Saint-Gilles, Raoul de Cambrai, Gaydon etc.
La Femme dans les Chansons de Geste. 37
position de la femme au XIII® siecle en comparaison avec
celle de la premiere partie du XII® ? Sans doute il ne serait
pas possible de dire que sa position etait plus ou moins mau-
vaise. Peut-etre, avait-elle plus de liberte, et plus de droits,
dans la societe, et, en revanche, elle avait perdu quelque chose
du respect, qu'elle inspirait autrefois aux esprits de ces hom-
mes rudes qui la veneraient tout en la maltraitant. C'est
possible qu'elle abusat un peu de sa nouvelle liberte—on le
fait toujours—au moins les idees de quelques poetes les plus
malins suggerent une telle interpretation.
On a fait mention plus haut d'une institution qui merite
ici un paragraphe. C'est les cours d'amour. De Lincy
dans son livr.e, "Les femmes celebres de I'ancienne France"
dit:^ "Ces assemblies paraissent s'etre formees des que la
premiere moitie du douzieme siecle au midi, et dans le nord,
vers 1140." Ces cours etaient des reunions des dames pour
juger des querelles d'amants, des chansons d'amour etc., et
De Lincy croit qu'eUes etaient de grande importance dans
la societe de I'epoque. Pour la plupart ses examples sont
bases sur le "Choix des poesies originales des troubadours"
de Raynouard, ecrivain provengal. Quant au midi nous n'en
disons rien, et il n'y a aucun doute qu'une telle institution
jouat la un role, mais il nous semble bien etrange qu'au nord,
pays des chansons de geste, une telle chose put exister et
fleurir pendant un siecle, le plus fecond de nos epiques, sans
que nous puissions en trouver. la moindre indication dans
les poemes. De plus, lorsque nous pensons a la condition de
la femme, au moins comme nous I'entendons, nous ne voyons
pas comment une telle institution soit possible. Nous ne
croyions pas les femmes du XII® siecle si independantes, si
hardies: et I'idee d'un Raoul, d'un Guillaume ou d'un Roland
qui paraisse devant une telle assemblee des dames, comme
competiteur pour le prix dans une chanson d'amour, nous
semble assez ridicule.
Quoiqu'il nous manque des textes pour decider la question
avec certitude, nous n'avons pu trouver aucunes preuves cer-
taines que ces cours fussent en vogue dans le nord de la France
' Voy. note audessus.
38
Colorado College Studies.
avant le milieu du XIII® siecle,^ et nous ne pouvons pas
comprendre pourquoi les poemes ne les mentionnerait pas si
elles y existaient. Si I'on pouvait determiner que ces cours
etaient connues seulement au midi pendant cette periode, ce
serait une autre preuve de la composition septentrionale de
la chanson de geste.
A regard done de la position de la femme en societe et
en droit, elle s'appellait I'egale de I'homme; mais on a vu que
cette egalite n'avait rien de vrai, parce que la force etait
souvent la loi, et la femme etait la plus faible. Aussi dans
quelques poemes, les plus vieux et les plus guerriers, la femme
compte pour peu de chose. Roland meurt en pensant a son
epee, a ses conquetes et a son seigneur, Charlemagne, mais
de la fiancee qui I'aimait si eperduement, pas un mot dans
cette belle oraison.^ On dit a la sage Ailis d'aller chez ses
femmes, de manger et de boire et de laisser les affaires aux
hommes.®
Mais tons les poemes ne sont pas des moeurs aussi farouches
et les droits de la femme etaient nombreux. Elle tenait
des fiefs, et elle pourrait peut-etre rejeter un mariage desa-
greable. EUe avait des missions importantes dans la religion
et dans la societe. Meme elle exercait quelquefois ce droit
le plus releve et le plus exclusif de la chevalerie, et elle
adoubait des chevaliers.* Mais c'est dans la vie domestique
qu'elle avait le pouvoir le plus grand. Elle adoucissait les
moeurs de ces barons farouches et, aidee par I'eglise elle
faisait beaucoup avancer le regne de la justice et de la pitie,
dans ces chMeaux feodaux, pendant ces deux siecles de demi-
obscurite. Enfin les poetes n'ont pas manque de nous don-
1 Martin: Histoire de la France.
2 Roland, V. 2259.
3Eaoul de Cambrai, V. 1100.
< C'est ce qu'elle fait en Doon de Maience (V. 8261), Caufrey (V.
3678), Gui de Nanteuil (V. 942) et Hugues Capet (V. 2060). Un des
meilleurs exemples est dans Li Covenans Vivien (V. 1270) oil Guiborc
donna I'accolade & Guichardet. M. Gautier donne aussi Auberon et
Jourdains de Blaivies. C'est clair que c'^tait assez commun pour ne
pas exciter I'^tonnement, mais nous ne le croyons pas reprfisentatif.
Cela n'etait pas un adouhement en rfegle.
La Femme dans les Chansons de Geste.
39
ner des types dignes de se comparer avec les femmes celebres
du monde entier. Ce sent Ailis la mere qui n'oubliait jamais
son fils, la belle Aude qui aimait Eoland mieux que les Fran-
gais de tous les siecles n'ont pu le faire. Ce sont la femme
guerriere, Guiborc, et enfin Berte la comtesse coutouriere,
type parfait de la chretienne du XII® siecle.
II y a une question qu'on fait sans cesse quand on parle
d'une periode quelconque de I'histoire. Quel fut le sort du
peuple? Fut-il heureux? Comment repondre a cette ques¬
tion an sujet de la femme du XII® siecle? Si le progres de
la civilisation du monde est tout bonnement une augmentation
des conditions qui produisent le bonheur, quel besoin de le
demander? Nous nous sommes certainement bien avances
depuis le XII® siecle. Mais il y avait aussi des causes spe-
ciales pourque le sort de la femme de cette epoque ne fut
pas le plus digne d'envie. Ce siecle etait en general le
regne de la force, et c'est toujours, aux epoques de violence,
la femme, le sexe plus faible, qui souffre les plus grandes
rigueurs. La femme du moyen age savait pleurer. C'etait
son metier a elle, et quelquefois toute son histoire. Un baron
dans Girart de Kossillon en priant un autre de quitter sa
douleur, dit: "Plorer doivent li femmes," et nous savons
qu'eUes n'en manquaient pas de causes et qu'elles pleuraient
bien. C'est une chose peut-etre pen connue des admirateurs
de 1 'antiquite, que nous avons des modeles de la douleur dignes
de comparer a celle si renommee pour le heros de la Troie.^
Dans ces croisades immenses contre les Mahometans de
1'orient, dans ces guerres contre les Sarrasins an midi de
1'Europe et ces expeditions contre les Saxons du nord, et
finalement, dans ces terribles luttes feodales entre des voisins,
que de femmes qui aimaient si bien leurs maris, femmes a
qui la vie avait commence si heureusement, devaient voir les
corps sanglants de ces forts et vigor,eux guerriers portes dans
la cour du cJjiMeau, ou, plus triste encore, attendre pendant
' Allis et la fiancee de Raoul, Hermenjart dans la ^dort Aymeri de
Narbonne et surtout Aude a. la mort de Roland.
40
Colorado College Studies.
longues annees les chevaliers qui ne retournaient plus! Que
de vies de femmes finissaient alors, comme finissent les plus
belles chansons de geste, sur un note monotone et triste.^
1 Comme Aliscans, Raoul de Cambrai, mais surtout. La Cbanson de
Roland. (On omet le biliographie A cause de T^tendue de la tb&se.)
AN INTERFEROMETER STUDY OF RADIATIONS
IN A MAGNETIC FIELD *
By Pbofessok J. C. Shedd.
In the historical development of this subject two well
marked experimental methods have been developed. The
first of these is the Spectrophotographic method used by Dr.
P. Zeeman and the majority of those who have followed. This
method is found to be limited, (1) in range by reason of the
small resolving power of the ruled grating, so that good
results are only obtained by using strong magnetic fields. It
is also limited, (2) in accuracy, by reason of the wide mar¬
gin of error in the settings of the micrometer, especially when
nebulous lines are to be measured.
The second method is due to Professor A. A. Michelson
and consists in the use of the interferential refractometer as
devised by him. This method is found to have a resolving
power greatly in excess of the photographic method, and hence
is applicable to low values as well as to high values of
magnetic field strength. The results so far accomplished
may be briefly summarized as follows:
I. By the Spectrophotographic Method.
(1) A classification of spectral lines according to the type
of line produced by the action of the magnetic field.
(2) The measurement of the change in wave-length pro¬
duced by the magnetic field, and a determination of
the ratio of ionic charge to ionic mass (e/m).
II. With the interferometer method Professor Michelson
has presented three well-marked types of lines with a possible
fourth type.
The experiments now to be briefly described have sought
to determine:
' See also Physikalische Zeitschrift, Vol. 1, No. 24.
42
Colorado College Studies.
I. The limiting conditions attending the observation of
the phenomenon.
II. A comparison of the ease of manipulation and range
of the two methods.
III. Whether at different temperatures the magnetic
effect is radically different.
IV. To measure the magnetic shift (i. e., change of wave¬
length) of the spectral lines examined, and to determine the
ratio e/m. Also to observe the state of polarization of the
components.
In the study of parts I., II. and III. the sodium flame and
sodium in a vacuum tube was made use of. The conclusions
reached were as follows:
I. (1) The magnetic shift of the sodium lines as
given by a naked flame, cannot, with the spectro¬
scope method, be distinctly observed at the tempera¬
ture of the Bunsen flame, nor of the air-blast flame,
nor at the temperature of the oxy-hydrogen flame,
unless precautions are taken against spontaneous
reversals.
(2) The phenomena can he better observed parallel to
the magnetic field than perpendicular to it, as the
strength of field necessary to produce a pure (i. e.,
visual) triplet is twice that necessary to produce
the doublet.
(3) There is a very perceptible time lag both when the
magnet is excited and when the current is broken,
during which time the spectral lines show an inertia
effect. The time lag does not seem to be wholly due
to the self-induction of the magnet, but may be par¬
tially due to persistence of vision and partially to
ionic inertia.
(4) A field strength of at least 15,000 C.G.S. units
seems to be necessary for satisfactory observation,
and spectra above the second order are too faint
for good effects.
Interferometer Study of Radiations. 43
II. (1) The interferometer is capable of showing the mag¬
netic effect for field strengths below 1,000 C.G.S.
units.
(2) The visibility curves,^ even under unfavorable cir¬
cumstances, show clearly the general character of
the magnetic action, and when checked through a
long series by means of an harmonic analyzer^ fur¬
nish an incomparable method of analysis.
(3) "When unaccompanied by such a check, and for
quantitative measurements of change of wave-length
another use of the interferometer furnishes a better
method.
III. (1) At the temperature of the Bunsen fiame there is
a distinct ionic "lag" or constraint which is sud¬
denly overcome, at a field strength of 9,500 C.G.S.
units.
(2) This ionic lag becomes less as the temperature
rises and is practically absent at the hottest tem¬
perature of the oxy-hydrogen fiame, or of the
vacuum tube.
(3) The change in wave-length reaches a maximum
value, depending upon the temperature, at about
^11,000 C.G.S. units. For values of magnetic field
above this the effect is to broaden the component
lines and not to further separate them.
This latter point may be peculiar to sodium and due to the
simultaneous presence of the lines D^D^. No observations
have yet been made upon these lines separately, the dispersion
necessary to isolate them being too great.
Measurements of Magnetic Shift.
The equation expressing the relation of the change of
wave-length (I — ^') to the strength of the magnetic field
(H) producing it is
'Phil. Mag. (5), 44, pp. 109-115, 1897; (5), 45, pp. 348-356, 1898.
'Phil. Mag. (5), 45, p. 85, 1898.
44
Colorado College Studies.
showing that for a given value of A the change of wave-length
should be proportional to the value of H, provided no con¬
straint is present. It is found that a constraint is present
at low temperatures, but disappears as the temperature rises.
The conditions of high temperature and low pressure are
best fulfilled by the vacuum tube and hence this was used as
a source of illumination. The arrangement of apparatus is
shown in Fig. 1.
The difficulties encountered were such as to reduce the
satisfactory observations to the lines of sodium, mercury,
cadium and zinc. The results are summarised in Table I.
and also shown graphically in Fig. 2.
Table I.
Magnetic sbift
Substance. Line. for H = 10,000.
Sodium'^ Yellow line. 0.414 A. U.
Mercury Yellow line. 0.256
Mercury Green line. 0.310
Mercury Violet line. 0.240
Cadmium Red line. 0.262
Cadmium Green line. 0.240
Cadmium Blue line. 0.274
Zinc Blue line. 0.288
^ The echelon spectroscope shows the separation of the com¬
ponents of P, to be about two thirds of that of P,. The value here
given belongs to P,, the line having the greatest magnetic shift.
Interferometer Study op Radutions. 45
Ratio of Ionic Charge to Ionic Mass.
The relation of ionie charge to ionic mass is given by the
equation:
ejm =
X — X' 2nv
X' H'
The numerical value of this ratio may now be determined
from the values of magnetic shift, and the corresponding
0.1 0.2 0.3 0.1
MAGNETIC SHIFT A'A' IN A.U.
Fig. 2.
values of iff. For the lines given in Table I. the values are
given in Table II.
Table II.
Substance. Line.
Sodium Yellow.
Mercury Violet.
Cadmium Blue.
Zinc Blue.
Mercury * Green.
Cadmium Green.
Mercury Yellow.
Cadmium Red.
Type of Lnie
elm (Michelson).
22.45 X 10'
23.81 X 10'
22.41 X 10'
23.46 X 10'
18.59 X 10'
17.48 X 10'
14.35 X 10'
11.93 X 10'
Type II.
j-Type III.
jxype I.
46
Colorado College Studies.
In the last column is added the corresponding grouping
of the lines as determined by Professor Michelson.^ It is
thus seen that the groupings made by Michelson according to
the structure of the spectral line is the same as that given
when the lines are grouped according to the value of the ratio
e/m.
A study of Tables I. and II. and Fig. 2 leads to the follow¬
ing conclusions:
(1) A classification of lines according to the amount of
magnetic shift is of little value; but a classification
according to the value of e/m is significant.
(2) The smaller the ratio e/m the less the broadening of
the component lines and the simpler the structure;
vice versa, the larger the ratio e/m the more the broad¬
ening and the more complex the structure.
Professor J. J. Thomson has shown that there is reason to
believe that the ionic charge is always a constant. If this
be applicable to the present case, we may conclude from Table
II. that the larger the ionic mass the simpler is the structure
of the line; and the smaller this ionic mass the more complex
the structure. We also conclude that the different spectral
lines of a substance are due to distinct ions.
' Astrophys. Jr., 7, p. 136, 1898; Nature, March 9, 1899.
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