B-1099
June 1970

 

Performance
of Small Grains
and Flax Varieties

in Texas

Texas A&M University

Texas Agricultural Experiment Station
H. O. Kunkel, Acting Director

College Station, Texas

- Summary

Small grains are used extensively for grain and sup-
plemental winter pasture in Texas. The combined acreage
of wheat, oats, barley and rye was 6,749,600 acres in 1968.
Only 4,255,900 acres were harvested for grain. Of the
2,493,700 acres not harvested, the majority was grazed to
maturity as the value for forage uses often exceeds that
for grain. Considerable acreages are abandoned each
year because of drouth or winter killing. Small acreages
are used for hay, grass silage or green manure. Small
grains are grown from the 50-inch rainfall belt of south-
east Texas to the 15-inch rainfall belt of northwest Texas.
Many varieties and types are needed for this wide range
of environmental conditions and the many uses made of
the crop.

Flax is grown from fall seeding as a cash grain crop

ADAPTED VARIETIES FOR GROWING AREAS

in South-central Texas. The first comm l,
flax were grown in 1958, and the acre 
529,000 acres in 1949. During recent y a
has ranged from 15,000 in 1957 to 169,000

Performance trials of small grains 
ducted at from 10 to 14 locations each year»
68. These trials serve as a means of - 
range of adaptation of commercial vari 
experimental strains developed in the br
For testing and easy reference, the state ~ 
Annual production, '
parable averages for grain yield and cc V;
characteristics for commercial varieties 
areas are given in tables which follow. Ail,
five best adapted varieties is given for each‘?
cases other varieties may be equally good

five research areas.

Area I II III
Extension
districts 1, 2 3, 6, 7 4, 5
Oats
FALL SEEDING
Cimarron Cimarron New Nortex
Wintok Norwin Ora
Bronco Nora Moregrain
Ora Alamo-X
Alamo-X Nora
SPRING SEEDING '
Co-ronado Cimarron Coronado
Cortez Coronado Cortez
Norwin Cortez Suregrain
Cimarron Ora
Barley
FALL SEEDING
Will Rogers Era
Harrison Cordova Cordova
Rogers Will Zora
Chase Era Rogers
Kearney Zora Will
SPRING SEEDING
Cordova Cordova Cordova
Rogers Rogers Era
Zora Era
Zora
Wheat
FALL SEEDING ,
Tascosa Caddo Sturdy
Caprock Scout 66 Caprock
Sturdy Sturdy Caddo
Caddo Caprock Knox 62
Scout 66 Improved Riley 67
Triumph Arthur
SPRING SEEDING
Not recommended
Flax

FALL SEEDING

  
    
  
 
   
 
 
 
  
  
  

IV

8, 9, 11

New Nortex
Coronado
Cortez

Ora
Moregrain

None recommended

Cordova
Zora
Rogers
Era

None recommended

Caddo
Sturdy
Caprock
Knox 62
Riley 67
Arthur

Dillman
Mac
Caldwell

Performance

of Small Grains
and Flax Varieties
in Texas

I. M. ATKINS*

Contents

Introduction ............................................................ -. 2
Summary ................................................................. -- 3
Research Areas and Test Locations ................. -- 4
Performance Trials ............................................... -- 4
Wheat .............................................................. -. 5
Rye ................................................................... --14
Oats .................................................................. .-14
Fall-Sown Performance Trials ............. ..21
Spring-Sown Performance Trials ........ .-25

Barley .............................................................. .25
Flax .................................................................. -33
Acknowledgments ............................... -.-. ................ .44

SMALL GRAINS OCCUPY A UNIQUE PLACE among Texas
crops because they are adapted to many uses and can
be grown with some degree of success from the 50-inch
rainfall belt of the Gulf Coast to the 15-inch rainfall belt
of Northwest Texas. Spring-type varieties can be fall-sown
in South Texas, while only very cold-tolerant varieties are
adapted to fall seeding in Northwest Texas.

Wheat is one of the important cash grain crops of
the High and Rolling Plains and to a lesser extent of
parts of the eastern half of theState. However, the forage
value of wheat, as winter pasture for livestock, has in-
creased greatly in recent years. Revenue from grazing
small grains, in terms of grazing fees, beef production or
milk production, is often equal to that received from the
grain crop.

Oats and barley are usually seeded in the fall,
although small acreages may be spring-sown when the
fall-sown crop has been winter-killed or when favorable
spring moisture is available. The fall-sown crop is used
as a combination winter forage and grain crop. When a
grain crop is to be harvested, livestock are removed from
the fields in February or March. As with wheat, large
acreages are grazed to maturity. They are seeded exclu-
sively for pasture with no intent to harvest a grain crop.
Smaller acreages are seeded for hay, grass silage, green-
chop feeding or as a green manure crop.

Rye is seeded for winter pasture, as a green manure
crop and for wind and water erosion control in sandy
areas. Only a small part of the rye crop is harvested for
grain production. Flax is grown only in South Texas
where it is fall-sown as a cash grain crop. In some seasons,
a very limited amount of the straw has been sold for the
fiber.

The seeded and harvested acreages of small grains
and flax are given in Table 1. The differences between
that seeded and harvested may be due to the acreage grazed
to maturity and that lost because of drouth, winterkilling,
diseases, storm damage or other hazards.

tProfessor and small grains and flax section leader, formerly

research agronomist, Crops Research Division, Agricultural Re-
search Service, U.S. Department of Agriculture, College Station.

3

TABLE 1. TEXASflO-YEAR AVERAGE ACREAGES AND
PRODUCTION OF SMALL GRAINS AND FLAX, 1959-68‘

lO-year average, 1959-68

Percent Pro- Yield
Seeded Harvested har- duction, per acre,
Crop acres acres vested bushels bushels
Wheat 4,315,100 5,278,700 76.0 65,904,300 20.1
Oats 1,896,700 750,600 38.5 18,720,500 25.6
Barley 367,700 219,900 59.8 4,810,700 21.9
Rye 172,100 26,700 15.5 592,400 14.7
Flax 109,700 82,300 75.0 778.100 9.5

‘Data furnished by the Texas Crop asd Livestock Reporting Serv-
ice, U.S. Department of Agriculture, Austin, Texas.

RESEARCH AREAS AND TEST LOCATIONS

Small grains and flax performance trials are designed
for two purposes: (1) To provide information on which
to base varietal recommendations to growers and (2) to
provide adequate tests of new experimental strains devel-
oped in the breeding programs. Data on performance of
commercial varieties are given in tables in the appropriate
sections. Data on experimental strains, for which no com-
mercial seed is available, are reported in mimeographed
form to research workers, Texas Agricultural Experiment
Station, Soil and Crop Sciences Department Technical
Report 25, 1968.

Because of the wide diversity of climatic conditions
in the state, five experimental or research testing areas
were established for reporting and easy reference, Figure
1. These represent general climatic and soil-type areas,
and each includes certain Texas Extension Districts. There

m, Research Extension
I1 area districts
"‘"“' T; -=- 1 1,2
Ln- mm wu- n mum II 3’6‘7
I3 L 111 4,5
_,,__ _____.. _,,:_ IV a,9,11
T 1"" v 10,12
&

     

a 1. Perryton I14. Denton l_
0 2. Etter 015. Sherman

I 3. Bushland I16. Overton

o 4. He11ington I17. McGv-egor

0 5. P1ainview I18. Temple

I 6. Lubbock I19. College Station
I 7. Chi11icothe I20. Prairie View

I 8. Iowa Park I21. Beaunont

I 9. Spur I22. Beevi11e

I10. Abilene 023. Robstown

I11. Pecos A I24. Crystal City

I12. E1 Paso I25. Heslaco
I13. San Ange1o

I F1e1d Units Texas Agricu1tura1 Experiment Station
o Cooperative Farm Research Sites

Figure 1. Small grains and flax research areas and testing

stations.

4

  
  
 
  
 
 
 
  
 
 
 
  
  
 
 
  
 
 
  
   
  
 
   
  
 
 
  
  
 
 
  
 
 
  
  
 
  
   
 
  
  
  
  
 
 
 
  
  
 
 
  

are some instances where the types of farming
exactly coincide with research or extension -,_’
these line limitations should be taken only 

Area I (Extension Districts 1 and 2).
Plains or Panhandle with elevation of 3000 ,_
and average rainfall of approximately 18 I?‘
temperatures are severe, and only hardy v i“
fall-sown successfully. Area II ,;(Districts 
the Rolling Plains, Trans-Pecos and no i
Plateau land-use areas. Rainfall ranges from”
the east to as low as 5 inches in the Trans-
tion water is only available in certain small 
quantity frequently is limited. The elevation‘:
but most small grains are grown at elevati
1750 feet. Winter temperatures are modera ~22‘
usually small grains remain dormant and 
damaged by low temperatures. Area III (
5) is the northern part of the Blacklands, i",
and East Texas Timberlands land-use areas.‘ 
ranges from 400 to 1500 feet with precipi
to 45 inches. Winter temperatures are o-i
ject to rapid change. A period of war i
cause small grains to initiate active growth -
ness. Cold fronts may then lower the tem
and seriously damage the crop. Soft red 
the major type grown in this area; oats - i
extensively. Area IV (Districts 8, 9 and 11. ,
part of the Blackland, Prairies, Cross TH» 
Southeast Texas Timberlands. Average preci n
from 3O inches on the western edge to near“? _
the upper Gulf Coast. Winter temperaturesf
and winterkilling of grain occurs only occ “f
V (Districts 1O and 12) is the southern.-
Blacklands and Prairies, plus the Coastal 
Grande Plain land-use areas. Precipitation _J~Y
distributed and ranges from 15 to 25 in 3i
water is available along some streams. 
wheat and other small grains used exclusive‘;
has recently increased. Practically all the T i
is grown in this area. '5

PERFORMANCE TRIALS

All performance trials were conducted _
plots arranged in randomized blocks of three
cations. These nursery plots were four 123i
by 1O to 12 feet long. The two center rows i’
to determine yields. Larger drill plots wet
for demonstration to provide seed or to pr i
samples for quality tests of wheat varieties. 

The varieties included in trials were A
quently as new ones became available and L’,
came obsolete. A set of standard checkij
maintained throughout the period of testing, 
ard varieties vary with research areas. In -I:v,
directly the varieties grown at a single l 
several years with check and other varieties 3'
period of years, comparable averages were 
comparable averages of grain yields and -;;!
were based on a selected set of check vari "A

   
 
    
   
  
  
  
   
 
  
   
 
  
  
  
 
  
  
   
   
  
   
    
  
  
  
 
    
  
 
  
  
   
  

Aperiod of years. The data for a variety grown a
‘ er period is adjusted on the basis of its performance
lation to the check varieties for the years when both
' grown. Actual yields and averages for shorter periods
lso given. Varieties tested for short periods may not
ccurately evaluated.

1 Recommendations are based on performance in grain
uction, but performance may be altered by such char-
istics as cold tolerance, disease reaction or insect resist-
‘i adaptation for winter grazing or quality of the wheat
i for milling purposes. Growers should consider all
- characteristics in selecting a variety to grow.

1A brief description of the growing seasons for the
'_ of testing herein reported is given:

: A favorable fall season; extremely dry winter and
1g season; heavy abandonment in western part of the
because of drouth; little winterkilling.

: A favorable fall season; cool, cloudy, damp winter
i above normal December rain and snow; January and
ary temperatures 4 to 10 degrees below normal, but
i, loss from winterkilling.

: Fall and winter very favorable; heavy snows from
on westward in January; December and January tem-
j res much below normal, but little winterkilling; very
pring with little disease losses.

: A favorable fall season; temperatures below nor-
{in fall followed by very severe January temperatures
a period of warm weather; serious low temperature

ted loss 14 percent of oat crop; forage of oats lost
a ghout State; total loss of grain and forage estimated
14 million; spring season dry and unfavorable for
ery; approximately 90 percent of the flax crop
oyed.

: Favorable fall season; early establishment and
rlant forage produced over entire state; severe winter-
gin January, estimated at 45 percent of the oats, 30
nt of the barley, 17 percent of the wheat and 30
nt of the flax; dry spring season unfavorable for
. “Y-

A: Fall season unfavorable; no rain until November,
winter over much of the state; much abandonment of
ges; little winterkilling; some stem rust damage to
t; damage to barley by Helminthosporium species.

:?Favorable fall; mild winter, no winter killing;
1mm spring; very wet May and June; moderate dam-
i- leaf rust on oats and wheat in Central Texas; severe
Vge to barley by Helminthosporium species.

 Favorable fall season; High Plains area very dry
J ghout fall and winter; other areas had favorable sea-
; flax diseases serious — rust, pasmo and boll rot.

' : One of the driest seasons on record; abandonment
; lowest acreage of oats harvested since 1881; March
~ caused much sterility of wheat in some areas.

-ge to stands and forage production of all small grains; _

1968: Excessive rains and flooding in South Texas due
to Hurricane Beulah; winter rains favorable; temperatures
uniform; little or no winterkilling; leaf rust of wheat
important in Central Texas and Rolling Plains.

Data on performance of varieties are arranged by
crops. The average grain yields are reported for the 5-
year period 1959-63. Annual yields are given for the
period 1964-68 and actual and comparable averages for
the 10-year period 1959-68.

WHEAT

The 10-year seeded average of wheat, 4,313,000 acres,
ranks third among cultivated crops in Texas. The seeded
acreage has been under government control for many years.
However, much of the wheat is grown in areas of limited
rainfall, so the seeded acreage fluctuates greatly, depending
upon moisture conditions at seeding time. The largest
acreages and production in Texas were in 1947 when
7,587,000 acres were seeded; 7,130,000 acres were har-
vested, and 116,960,000 bushels of grain were produced.
The lowest seeded acreage since 1925 was in 1955 when
1,508,000 acres were seeded, and production was 14,326,000
bushels.

Wheat acreage is widely distributed in Texas, Figure 2.
Approximately 53 percent was grown in Research Area I
and 32 percent in Research Area II in 1968. Due to the
release of Milam and other adapted varieties, the acreage
in Research Area V has increased from only a few thou-
sand acres in 1950 to more than 160,000 acres in 1968.
The wheat acreages by extension districts and research areas
are given in Table 2.

Nearly all Texas wheat is fall-sown. However, in
favorable spring seasons or in irrigated areas, a small acre-
age of true spring-type varieties may be spring-sown in
Northwest Texas. Spring-type varieties may be fall-sown

   
 

WHEAT
ACRES PIANTED 1968

    

  

l Dot = 1,000 Acres

Figure 2. Distribution of 1968 Texas wheat acreage.

TABLE 2. ACREAGES AND PRODUCTION OF

1968‘

WHEAT BY EXTENSION DISTRICTS AND RESEARCH "g1

Exten- Research

Percent of each
district of state

sion testing Average Average
district area Land use area seeded harvested Seeded Harvested
1 I Northern High Plains 2,139,650 1,660,690 43.6 43.3
2 I Southern High Plains 520,950 368,000 10.6 9.6
3 II Northern Low Rolling Plains 1,101,300 956,230 22.4 25.0
6 II Trans-Pecos 33,550 24,340 0.7 0.6
7 II Southern Low Rolling Plains 319,350 261,200 6.5 6.8
and upper Edwards Plateau
4 III North Central Blacklands, 401,200 328,100 8.2 8.6
Prairies and Cross Timbers
5 III Northeast Timberlands 16,000 7,850 0.3 0.2
8 IV Central Blacklands, Prairies 192,800 126,900 3.9 3.3
and Cross Timbers
9 IV Central East Timberlands 1,800 0
11 IV Southeast Texas and upper Coast 21,270 2,290 0.4 0.1
10 V South Central Blacklands 124,640 69,500 2.5 1.8
Prairies and Coastal Bend
12 V Rio Grande Plain, South Texas 36,490 19,900 0.7 0.5

‘Texas Small Grain Statistics, Bulletin No. 50, May, 1969, USDA, Statistical Reporting Service, Austin, Texas, 1968.

TABLE 3.
BUSHLAND, 1958-68‘

GRAIN YIELDS AND AGRONOMIC DATA FOR WHEAT VARIETIES GROWN WITHOUT

Yield of grain, bushels per acre

1963-682 1958-68
Average Average Number Com- Date
for years for years years para.ble

Variety 1964 1966 1968 grown grown grown average“
Comanche‘ 14.6 10.6 22.4 15.9 18.5 7 18.5
Early Blackhull‘ 12.0 15.1 22.0 16.4 20.0 7 20.0
Kharkof‘ 16.8 10.6 21.2 16.2 18.5 7 18.5

Average 14.5 12.1 21.9 19.0 7 19.0
Agent 10.2 1 10.1
Aztec 21.2 3 19.0
Bison 16.5 8.8 12.7 19.1 6 19.6
Caddo 15.2 14.6 23.7 17.8 20.5 7 20.5
Caprock 11.3 24.0 17.7 17.7 2 19.7
Concho 22.8 3 20.7
Crockett 15.4 23.5 19.5 19.9 6 18.8
Gage 13.7 13.7 15.3 3 19.2
Gaines 8.5 9.7 9.1 9.1 2 14.8
Guide 17.0 16.7 23.8 19.2 19.2 3 22.0
Kaw 16.2 16.2 19.9 4 20.8
Lancer 14.4 14.4 14.4 1 18.9
Ottawa 15.3 10.8 13.1 14.8 4 19.4
Parker 13.8 24.5 19.2 19.4 3 19.9
Ponca 26.6 3 21.4 5-11
Red Chief 23.7 3 18.5 5-12
Scout 16.8 14.0 23.3 18.0 17.2 4 21.0 5-7
Scout 66 13.6 22.3 18.0 18.0 2 20.0 5-6
Shawnee 10.8 21.6 16.2 16.2 2 18.2
Sturdy 12.5 11.3 22.2 15.3 15.3 3 18.2 5-6
Tascosa , 12.8 14.7 21.7 16.4 20.9 7 20.9 52s
Triumph 17.8 10.1 19.9 15.9 17.2 6 18.5 5-5
Triumph, Improved 15.3 14.3 20.9 16.8 17.9 6 19.2 5-4
Triumph "'64 16.4 1.3.9 22.7 17.7 17.7 3 20.5 5-3
Warrior 14.2 14.2 12.3 2 18.1 5-11
Westar 25.3 3 20.1 5-11
Wichita 21.2 4 19.0 5-6
LSD— 5 percent 3.6 4.2 6.1

‘Hailed out in 1961.
’Hailed out in 1963 and 1965.
‘Calculated comparable yields based on years grown.

‘Check varieties used for calculating comparable needs.

6

    

» IRRIGATION AT WELLINGTON, 1959-68‘

4. ANNUAL, AVERAGE AND COMPARABLE GRAIN YIELDS OF WINTER WHEAT VARIETIES GROWN WITH-

Yield of grain, bushels per acre

   

1959-63 1964-68 1959-68
Average Number Average Number Average Number Com-
for years years for years years for years years parable
grown grown 1 964 1965 1966 1 967 grown grown grown grown average’

1' Blackhull“ 22.0 5 11.7 14.6 10.9 15.2 13.1 4 18.1 9 18.1

. . the” 26.0 5 9.8 17.0 13.4 15.0 13.8 4 20.6 9 20.6

 of“ 26.8 5 6.1 13.5 11.3 15.0 11.5 4 20.0 9 20.0

verage 25.0 5 9.2 15.0 11.9 15.1 12.8 4 19.6 9 19.6

i.’ 30.5 5 12.3 13.0 12.7 12.7 3 23.8 8 23.2

do 24.9 5 11.4 14.5 13.1 13.8 13.2 4 19.7 9 19.7

ock 10.6 11.4 11.0 2 11.0 2 17.1

.- ett 27.2 5 14.1 14.1 ~ 1 25.0 6 22.3

36.2 3 15.1 14.6 14.8 14.8 3 25.5 ‘ 6 22.4

15.6 2 11 1 11.1 1 14.1 3 20.4

13.6 1 13.1. 13.1 1 13.4 2 19.7

25.9 5 11.5 14.3 12.9 2 22.2 7 20.4

15.8 16.1 16.0 2 16.0 2 23.4

24.4 3 8.7 8.7 1 20.5 4 21.5

31.9 3 31.9 3 20.1

, 24.0 3 24.0 3 21.1

,' 12.7 13.1 14.2 15.5 13.9 4 13.9 4 20.6

vy 13.3 9.1 12.7 9.1 10.4 10.3 4 13.7 5 17.3

n a 27.4 5 15.7 12.6 13.0 11.0 13.1 4 21.0 9 21.0

fpl‘! 24.3 5 15.3 15.3 1 22.5 5 19.9

"l ph, Improved 25.4 4 13 4 17.4 12.8 14.9 14.6 4 20.0 8 20.5

a = ph '64 13.2 12.6 12.9 2 12.9 2 18.9

j ior 16.0 2 13.5 15.6 14.6 2 15.3 4 21.1

"ta 30.6 3 30.6 3 18.8
V! — 5 percent 2.8 2.1

  

   
   
   
   
  
   
  
   
   
   
   
  
   
    
 
   
 
   

I data for 1968.
culated yield based on years grown.
k varieties used for calculating comparable yields.

gSouth Texas where winters are mild. Some spring
eties have no critical photoperiodic requirement to
“te heading. These varieties, called day-length neutral
'eties, will initiate heading when favorable temperatures
reached. Such varieties may head in mid-winter in
th Texas if planted too early. Other varieties are sensi-
~ to day length and will not head until days become
‘er in the spring. Thus, photoperiodic response is an
rtant factor to consider in choosing a variety for plant-
_ and the proper time to plant.

True winter-type varieties vary greatly in cold toler-
- even though most have narrow leaves and prostrate
wing seedlings. Most require a period of vernalization
w growth under cool temperatures) to head normally.
few varieties are somewhat intermediate in growth habit,
l they are not comparable to intermediate-winter type
leys because they do require some vernalization. These
uce erect growing seedlings with broad leaves. Addi-
 al characteristics of varieties are available in Texas
icultural Experiment Station Bulletin 1095, "Wheat
uction in Texas."

SEARCH AREA I; The High Plains is the major wheat
in growing area with almost 44 percent of the State's
eage in Extension District I alone. About half of this
i irriagtedl. Only cold tolerant winter-type varieties

igh Plains Irrigation Survey 1968. Texas Agricultural Exten-
jn Service—mimeographed. Compiled by Leon New. area
gation specialist.

should be fall-sown. Drouth is a major hazard where
irrigation is not available, and when drouth is combined
with low temperature injury, major losses may occur. Hail
also is an important hazard of production.

Performance trials have been conducted without irriga-
tion at Bushland and Wellington, Tables 3 and 4. At
Wellington, the highest comparable yields were produced
by Lancer, Bison, Concho, Crockett, Ottawa and Warrior.
Some of these were not grown long enough to be properly
evaluated. At Bushland, the leading varieties in yield
were Guide, Ponca, Scout, Tascosa, and Kaw. Differences
were small among these leading varieties at both locations.

Performance trials under irrigation were conducted at
Bushland, Hartley, Etter, Stratford, Perryton and Plain-
view. Data for the full period are available only from
Bushland, Table 5. The highest comparable yields at
Bushland were produced by Shawnee, Caprock, Tascosa,
Scout and Parker. Several of these have been tested for
only short periods. At Etter, (3 years) Table 6, the
highest yields were produced by Concho, Scout, Improved
Triumph, Tascosa and Warrior. At Hartley in 1968,
Table 6, Concho, Scout, Sturdy and Parker produced the
best yields. At Stratford, (4 years) Table 7, Scout, War-
rior, Tascosa, Concho and Improved Triumph produced
the highest yields.

At Perryton, (4 years) Table 8, the best comparable
yields were produced by Scout, Kaw, Gage, Lancer and

7

   
  
    
   
  
  
     
     

TABLE 5. ANNUAL, AVERAGE AND COMPARABLE YIELDS OF IRRIGATED WINTER WHEAT AT BUSHL A

Yield of grain, bushels per acre _ ,
1965-68’ 1958-68 

Average Number Average Number 
for years years for years years
Variety 1964 1966 1967 1968 grown grown grown grown

Comanche‘ 57.9 50.3 56.0 60.6 56.2 4 51,5 8
Early Blackhull‘ 50.7 37.8 49.0 58.1 48.9 4 4656 8
Kharkof‘ 59.0 58.4 40.7 46.4 46.1 4 4350 8

Average 55.9 42.2 48.6 55.0 50.4 4 47.1 8
Agent 26.1 1
Aztec A 44.3 4
Bison 62.3 57.8 52.1 57.4 3 51.9 7
Caddo 51.9 54.5 54.0 62.4 55.7 4 62.2 8
Caprock 65.2 59.2 71.7 70.6 66.7 4 66.7 4
Concho 49.2 4
Crockett 57.7 63.1 60.4 2 48.1 6
Gage 57.6 57.6 1 50.0 3 ’
Gaines 67.7 31.8 49.8 2 49.8 2
Guide 58.6 51.7 53.8 65.6 57.4 4 57.4 4
Kaw 54.4 53.7 54.1 2 53.5 5
Lancer 65.6 65.6 1 65.6 1
Ottawa 57.6 57.6 1 52.0 3
Parker 62.0 62.7 62.4 2 67.3 3
Pawnee 44.4 2
Ponca 48.8 3
Red Chief 44.0 3
Scout 69.8 57.7 55.4 68.7 62.9 4 59.4 5
Scout 66 56.0 62.4 60.0 59.5 3 59.5 3
Shawnee 55.0 70.6 69.3 65.0 3 65.0 3
Sturdy 61.4 47.9 62.6 65.8 59.4 4 59.4 4
Tascosa 73.4 68.3 63.6 65.9 67.8 4 59.8 8
Triumph 51.8 46.8 53.2 53.0 51.2 4 52.0 7
Triumph, Improved 62.4 48.9 55.8 57.0 56.0 4 55.9 7
Triumph '64 55.7 45.9 53.1 56.7 52.9 4 52.9 4 ‘
Trader 52.1 52.1 1 52.1 1
Trapper 58.8 58.8 1 58.8 1
Warrior 65.3 65.3 1 55.6
Westar ' 46.0
Wichita 33.2 47.0 40.1 2 37.4
LSD — 5 percent 8.2 10.4 7.8 12.9

‘Destroyed by hail in 1961.

‘Destroyed by hail in 1963 and 1965.

“Calculated comparable data based on years grown.
‘Check varieties used to calculate comparable yields.

TABLE 6. ANNUAL, AVERAGE AND COMPARABLE YIELD} OF IRRIGATED WINTER WHEAT VARIETIIQ
ETTER AND HARTLEY, 1965-68 -

Etter, yield per acre, bushels

Average Comparable‘ G f
For Test Plant y' '_
years Com- weight, height, .1... ._

Variety 1965 1966 1967 grown parable‘ pounds inches pet f’,
Early Blackhull’ 68.2 48.7 37.7 51.5 51.5 60.7 33.0
Comanche’ 68.9 42.9 43.6 51.8 51.8 59.1 38.0
Kharkof’ 61.4 35.5 33.6 43.5 43.5 57.5 38.3

Average . 66.2 42.4 38.3 48.9 59.1 36.4
Bison 50.2 44.3 47.3 55.8 60.5 34.6
Caddo 65.7 48.7 42.8 52.4 52.4 62.0 32.7
Concho 54.5 54.5 65.1 57.9 35.7
Caprock 58.8 59.2 38.1 52.0 52.0 59.0 27.0
Gaines 47.2 47.1 53.7 53.6 23.4
Lancer 64.6 64.6 47.3 60.9 37.7
Parkier
Scout 81.3 49.1 50.2 60.2 60.2 60.7 36.6
Sturdy 76.1 47.7 55.0 52.9 52.9 59.1 28.5
Tascosa 81.8 42.1 47.5 57.1 57.1 63.2 33.3
Triumph, Improved 78.1 57.5 35.9 57.2 57.2 60.7 30.3
Triumph 64 51.2 40.5 45.9 54.4 61.1 32.1
Warrior 74.2 74.2 56.9 59.2 36.7
LSD———- 5 percent 8.3 14.2

‘Calculated comparable average based on years grown.
‘Check varieties usecl for computing comparable data.

8

 
   

I LE 7.
.» TFORD, 1958-68

ANNUAL, AVERAGE AND COMPARABLE GRAIN YIELDS OF IRRIGATED WINTER WHEAT GROWN AT

Yield of grain, bushels per acre

 

 

  
    

 
 
 
 

1958-62 1963-66 1958-66
Average Number Average Number Average Number Com-
for years years for years years for years years parable
iety grown grown 1963 1964 1965 1966 grown grown grown grown average‘
ly Blackhull’ 38.0 4 30.5 60.2 41.5 32.8 41.3 4 59.6 8 59.6
,1 nche’ 55.8 4 51.5 55.5 56.7 52.5 58.5 4 57.4 8 57.4
mkof’ 36.5 4 31.8 42.0 36.6 30.4 35.2 4 35.9 8 35.9
. verage 36.8 4 31.2 51.9 38.3 31.9 38.3 4 37.6 8 37.6
6C 55.4 5 55.4 5 57.2
n 41.0 4 40.0 57.0 51.3 42.8 5 41.7 7 41.8
do 57.8 3 29.8 66.4 59.9 51.8 42.0 4 43.1 7 40.7
rock 32.6 32.6 1 32.6 -1 38.3
cho 42.7 3 42.7 3 44.5
5 ett 37.9 4 34.9 34.4 34.7 2 36.8 6 36.0
C 44.0 1 54.6 52.5 45.5 2 45.6 5 40.0
‘1- 16.4 34.4 25.4 2 25.4 2 51.5
35.2 3 34.9 48.8 47.6 43.8 3 40.3 5 40.2
er 48.6 40.1 44.4 2 44.4 2 36.9
wa 42.3 1 33.6 51.4 42.5 2 42.4 3 38.8
’ a 40.1 2 40.1 2 37.4
- Chief 34.5 3 34.5 3 36.3
; t 70.8 44.9 41.5 52.4 5 52.4 5 49.5
dy 23.0 58.8 46.4 32.6 41.5 4 41.5 4 40.7
I sa 44.7 4 31.1 63.4 42.8 41.6 44.7 4 44.7 8 44.7
' ph 57.8 2 24.8 65.5 45.1 2 41.4 4 41.5
i ph, Improved 36.9 2 34.5 69.3 42.8 37.7 46.1 4 43.0 6 43.8
a ph, Super 32.7 2 32.7 2 36.5
- ph 64 26.2 26.2 1 26.2 1 51.9
I101‘ 51.2 1 40.5 58.2 45.0 47.9 5 48.7 4 45.9
ita 36.4 3 36.4 3 38.1
-— 5 percent 6.3 9.0 8.1 5.3

  

 
    
  
   
  
   
  
  
   
  
  
   
   
 
 
   
   
   

i. lated comparable average based on years grown.
' k varieties used to calculate comparable data.

A ldy. Concho was grown for only 1 year. At Plainview,
' _ years) Table 8, Scout, Comanche, Concho, Bison and
p.osa produced the best yields.

i iAgronomic data at Bushland, Table 3, show Red
f, Kaw, Aztec, Caprock, Caddo and Tascosa had the
test weight. The Triumph strains and Early Blackhull
" the earliest in maturity, although Sturdy and several
=. were only slightly later. No lodging was recorded
31g the period, but Gaines, Sturdy, Caprock and Lancer
p the shortest strains.

ARCH AREA II: Extension District 3 of this area
 s approximately 22 percent of the State's acreage. In
1: 87 percent of the planted acreage was harvested,
in seasons of drouth, which are frequent, a smaller
i tage is harvested. Most of the Trans-Pecos area is
e51 to ranching. Performance trials were conducted at
 Park until 1965, Table 9, and for the full period at

'cothe, Table 10. The highest comparable yields at
‘ Park were produced by Gage, Kaw, Concho, Improved
i. ph, Ottawa, Crockett and Tascosa.

Comparable data at {Chillicothe for the full period
: Scout 66, Scout, Caprock, Newest Improved Triumph
Sturdy as the five leading varieties, although differ-
'1. among them are small. Several Triumph strains
tested, but as only foundation seed of Improved
ph and Triumph 64 are now available, data for the

others are not included. The new short stature wheats,
Caprock and Sturdy, have produced well at Chillicothe.

Comparable agronomic data, Table 10, show that Kaw,
Ponca, Kaw 61, Aztec and Triumph (Metcalf) have the
best test weight. Sturdy and Caprock are approximately as
early as the Triumph strains with Guide, Caddo and
Crockett emerging slightly later. Sturdy and Caprock were
from 7 to 8 inches shorter than older varieties and have
shown advantages in resistance to lodging.

RESEARCH AREA III: Approximately 8 percent of the
State's acreage is grown in Extension District 4 and only
a small acreage in District 5. The commercial acreages of
this area are predominantly of the Knox or Knox 62
varieties. Caddo, Improved Triumph, Sturdy and Crockett
are the other important varieties grown. Performance
trials were grown at Denton throughout the period and
in a few seasons at Mt. Pleasant or Overton. Data at
these latter locations are extremely variable but indicate the
yields that might be expected.

Performance data at Denton, Table 11, show that the
soft winter wheat varieties have the best comparable yields,
although the leading ones have not been tested extensively.
Arthur, Benhur, Riley 67 and Stadler have the highest
comparable yields. Knox and Knox 62, which were grown
for longer periods, have averaged about the same yields
as Caddo and Gage. The best hard winter wheats were

9

 

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l0

  

LE 9. ANNUAL, AVERAGE AND COMPARABLE YIELDS OF WINTER WHEAT AT IOWA PARK, 1956-65‘

Yield of grain, bushels per acre

  
     
  
    
   

Average Number Com-
y for years years parable
iety 1956 1957 1959 1960 1961 1962 1963 grown grown yield’
» anche“ 57.0 25.4 44.5 57.0 31.5 23.4 37.6 39.5 7 39.5
» kett“ 57.6 25.0 46.8 62.1 57.1 29.8 55.4 44.5 7 44.5
ly Blackhull” 60.1 26.7 47.3 58.5 30.3 29.0 41.3 41.9 7 41.9
»< kof“ 55.6 22.3 43.0 46.0 30.5 19.1 30.6 35.3 7 35.3
. m“ 64.2 25.4 55.5 61.8 54.1 25.0 46.0 44.0 7 44.0
" verage 58.9 25.0 47.0 57.1 32.7 24.9 41.8 41.0 7 41.0
ec 44.1 55.8 31.8 43.9 3 39.3
.v 22.2 45.5 64.6 37.6 24.9 45.7 40.1 6 43.1
d0 41.1 60.2 30.7 29.1 47.0 41.6 5 41.9
G110 67.1 23.2 50.8 65.8 35.8 48.5 5 45.4
 34.4 28.8 49.8 37.7 3 45.6
49.2 61.5 51.6 55.8 47.7 45.2 ' 5 45.5
wa 31.2 44.0 37.6 2 45.3
l a 55.5 25.6 40.2 58.0 38.6 43.6 5 40.5
 Chief 55.2 23.6 42.4 46.0 29.3 39.3 5 36.2
A. o 32.1 24.8 38.0 31.6 3 39.6
'dy 41.4 41.4 1 40.7
n rq 55.7 26.4 42.6 41.6 5 59.0
ph 25.8 42.6 57.2 31.5 31.8 38.0 37.8 6 40.8
g ph, Improved 44.2 69.8 34.2 34.5 40.0 44.5 5 . 44.9
» ph, Super 34.1 28.2 31.2 2 43.4
rior 20.2 41.7 30.9 2 38.7
-- 57.2 21.9 47.4 42.2 3 39.6
~ 'ta 64.2 25.1 41.4 59.0 47.4 4 41.5
—5 percent 8.2 3.7 8.9 10.3 4.9 5.7 7.5

  

  
  
   
 
    
  
  
  
    
   
   
  
    
   
  

Z lated comparable yield based on years grown.
varieties used to calculate comparable yields.

er, Caddo, Sturdy, Gage and Triumph 64.
a Agent have not been fully evaluated.

i Agronomic data show Kaw, Caddo, Parker, Triumph
and Arthur with the best test weight. Sturdy and
= ock are equally as early as the Knox and Riley strains
g average about 6 inches shorter, an advantage in resist-
" to lodging.

3 A few varieties have been tested in East Texas, Table
gas part of a forage evaluation project.

i ARCH AREA IV: Approximately 4 percent of the
's acreage is grown in Extension District 8 and only
»-- l acreage in District 9. Both hard and soft winter
t and a few durum varieties are grown commercially.
 largest commercial acreages are devoted to Caddo,
v ah and Crockett. Performance trials were conducted
emple and McGregor. Comparable data for Temple,
1e13, show Riley 67, Benhur and Sturdy as the leading
‘es. Arthur has not been thoroughly tested. The
varieties also have produced good yields, but there
g local market for them, so they must be used for feed.
A best test weights were produced by Kaw, Stewart
_ , Knox 62, Caddoziand Arthur. Lodging is impor-

in this area, and Sturdy and Caprock were the shortest
j' s and among the earliest in maturity.

'At McGregor, Table 14, the highest comparable
_,~ were produced by Gage, Knox, Wells durum and
do. Knox 62, Sturdy and Kaw yielded almost as

Parker _

i-- lost due to poor stand in 1958 and hail damage in 1964 and 1965.

much as the leading varieties. The highest test weights
were produced by Caddo, Riley, Stewart durum, Riley 67
and Knox 62. The soft wheat varieties Riley and Riley
67 and Knox and Knox 62 were the earliest in maturity
but only a few days earlier than Sturdy. Leaf rust is
important in this area, and the lowest infections were
observed on Agent, Riley 67, the durum varieties and
Quanah.

RESEARCH AREA V: The acreage of wheat has expanded
in this area since the release of Milam wheat in 1960. The
seeded acreage in 1968 was about 3 percent of the State's
acreage, but only about half of this was harvested. Most
of the acreage is grown in Extension District 10. The
Mexican variety, Penjamo 62, is now being grown on a
small acreage.

Spring-type varieties may be fall-sown in this area, so
data for hard red winter, soft red winter, durum and hard
red spring varieties were obtained. At College Station,
Table 15, the highest yields for a period of years were
produced by the durum varieties Lakota, Stewart, Langdon
and Sentry, although the yield of Milam was not signifi-
cantly less. Chris and Crim hard red spring wheats pro-
duced rather low yields because they were damaged by
spring freezes in several seasons. The durum wheat varie-
ties also produced the highest test weight grain, although
that of Milam also was above standard. Leaf rust is
important in this area and may be a factor in the high yields
of the durum varieties.

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TABLE 12. YIELDS OF FALL-SOWN WHEAT VARIETIES
AT MT. PLEASANT ‘AND OVERTON, 1955-68

Mt. Pleasant Overton

Variety 1955 1963 1968
Frisco 8.1

Knox 7.7

Atlas 9.7

Quanah 2.8 16.3 17.1
Caddo 34.7

Milam I7. l 28.1
Sturdy 26.5

Comparable yields at Beeville, Table 16, show the
highest yields produced by Penjamo 62, Rio Bravo, Lerma
Rojo and Nadadores. However, these were tested only
1 to 3 years. The durum varieties have yielded well. Rust
is important at this location, and the durum varieties have
been highly resistant. However, races which can attack
most durum varieties are now present. Milam has produced
as well as the spring wheat varieties and better than the
winter-type varieties Quanah, Caddo and Sturdy.

RYE

The rye acreage is rather widely distributed over
Texas, Figure 3, but it is grown more extensively on the
sandy-textured soils of each area. On such soils it usually
produces more forage and grain than do the other small
grains. It frequently is grown with vetch or winter peas as
a soil building, wind and water erosion control crop and for
winter pasture or other forage uses. The relatively new,
erect growing forage rye varieties, such as Elbon, Bonel,
Gator, etc., are now widely grown on many types of soils
for winter pasture. Only 15 percent of the seeded crop is
harvested for grain, Table 1.

 
  
   
    

RYE
ACRES PLANrED 1968

l Dot = 1,000 Acres

Figure 3. Distribution of 1968 Texas rye acreage.
14

OATS
ACRES PLANTED 1968

‘l Dot = 1,000 Acres

Figure 4. Distribution of 1968 Texas seeded acreage of.

Performance trials have been grown at M
from 1961-68 but only in occasional years at other‘
Data at Chillicothe, Table 17, shows relatively i
ferences in yield among the strains tested. Ca _
in nearby tests at Chillicothe averaged 22.2 b i,
acre for the same 8-year period. J

At Denton, Table 18, the yield of Elbon rye
bushels per acre for the 2 years 1960-61. Cad,
in nearby tests averaged 40.0 bushels per acre. P.
lege Station on sandy land, Elbon rye yielded 31.3,
compared to 20.9 bushels for Milam wheat. In j
on sandy soils at Overton and Mt. Pleasant rye 
wheat in most seasons i.e., Elbon rye 43.2 A
wheat 28.1 bushels in 1968 at Overton. 

OATS

The oat acreage in Texas is widely distribut if
4, and because it is used so extensively for livest
the seeded acreage fluctuates widely in accordan 
conditions for fall seeding. During the past 10.}?
than 4O percent of the seeded acreage has beenifi
Table 1. Oat acreages have declined to some
recent years. After the severe spring drouth:
only 315,000 acres were harvested from the i
seeded. This was the lowest-harvested acreage f‘
The greatest acreage of oats ever grown in T l
1957 when 2,670,000 acres were seeded.

Most Texas oats are fall-sown, but a small
spring-sown in Northwest Texas each season, i
winterkilling reduces the fall-sown crop, the spf
acreage is increased. Fall-sown oats usually pr 
yields and better quality grain than spring-sown 
acreages of oats in 1968 by extension districts
areas are given in Table 19. The largest

15

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 LE 17.

ANNUAL AND AVERAGE YIELDS OF FALL-SOWN RYE VARIETIES AT CHILLICOTHE, 1961-68

Average Average, 1965-68

For Elbon Date

years for same Test first

1961 1962 1965 1964 1965 1966 1967 1968 grown years weight head
25.7 8.8 21.2 11.5 14.8 5.9 19.0 I9.4 15.5 14.2 54.5 4-25
21.7 10.5 19.2 11.1 15.7 6.4 21.8 14.6 15.1 14.2 55.8 4-17
18.5 8.9 16.6 15.1 15.5 11.1 22.9 11.7 14.8 14.2 54.5 4-18
18.6 11.9 17.1 12.9 15.1 10.6 19.2 15.1 14.8 14.2 54.8 4-18
19.4 10.4 14.7 12.8 15.7 10.0 21.4 11.5 14.2 54.2 4-17
20.8 14.1 17.2 7.0 20.2 14.1 15.6 14.0 54.5 4-21

15.1 9.1 20.0 11.8 15.5 14.1 55.5 4-18

12.] 9.4 20.4 10.7 15.2 14.1 55.8 4-18

20.0 9.9 15.0 16.4

i LE 18. GRAIN YIELDS AND AGRONOMIC DATA FOR
. PLEASANT AND OVERTON, 1955-68

RYE VARIETIES GROWN AT DENTON, COLLEGE STATION,

v XAS, 1968‘

Denton College Station, 1962
Grain yield, bushels Test Grain Test Percent
weight, yield, weight, leaf
1 960 1 96 1 Average pounds bushels pounds rust
55.1 40.5 56.7 56.0 27.5 57.0 10
51.0 44.4 57.7 57.0 51.5 57.0 40
59.5 26.2 52.8 58.0
40.8 58.0 50.6 56.0 10
4.8 80
51.7 57.0 20
27.8 57.0 10
Mt. Pleasant Overton
Grain yield, bushels
1955 1956 1957 1965 1964 1968
20.9 26.8 55.5 26.0
54.0 45.2
17.8
20.7 55.8
45.4

A LE 19. ACREAGES AND PRODUCTION OF OATS BY EXTENSION DISTRICTS AND RESEARCH TESTING AREAS IN

Percent
Percent of state of seeded
. Research Pro- acreage
tension testing Acreage Acreage Total Total duction, harvested
trict area Land use area seeded harvested seeded harvested bushels for grain
1 I Northern High Plains 15,510 7,590 0.85 1.50 205,000 56.2
2 I Southern High Plains 16,720 6,590 1.05 1.15 181,420 59.4
,5 II Northern Low Rolling Plains 150,600 81,770 9.21 14.02 2,987,000 54.5
6 II Trans-Pecos 8,550 4,250 0.51 0.75 158,500 50.7
7 II Southern Rolling Plains and 501,280 184,070 18.50 51.50 6,440,500 61.1
Edwards Plateau 242,950 106,580 14.91 18.28 4,060,900 45.9
4 III North Central Blacklands,
Prairies and Cross Timbers
5 III Northeast Texas Timberlands 54,280 8,100 2.11 1.47 282,550 25.6
3 IV Central Blacklands, 574,950 149,820 25.00 25.65 4,588,700 40.0
Prairies and Cross Timbers
9 IV Central East Timberlands 50,650 1,590 5.11 0.24 57,700 2.7
10 IV Upper Coast and Southeast 86,750 2,210 5.55 0.58 48,750 2.5
Texas Timberlands
11 V South Central Blacklands, 212,500 12,150 15.05 2.08 505,400 5.7
Prairies and Coastal Bend
12 V Rio Grande Plain, South Texas 154,770 18,550 8.28 5.15 502,700 15.6

exas Small Grain Statistics, Bulletin N0. 50, March 1969, USDA, Statistical Reporting Service, Austin, Texas.

l9

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20

ABLE 21. COMPARABLE GRAIN YIELDS AND AGRONOMIC DATA FOR IRRIGATED, FALL-SOWN OAT VARIETIES
ROWN AT PLAINVIEW, ETTER AND FLOYDADA, 1956-68
Comparable yield of grain‘ Comparable‘ Plant Winter
Plainview Etter Floydada Test weight, pounds height, Sufvlval, Lodging.
“ inches percent percent
ariety 1966-67 1966-67 1956-60 Plainview Etter Floydada Floydada 1966 1966
_1'0I1CO2 96.9 104.1 55.4 33.1 32.0 36.2 25.3 8O 32
' 'marron’ 119.8 106.5 48.9 34.0 34.5 35.6 21.8 78 55
J OiS 103.9 99.0 37.7 34.4 75 32
razier 100.4 51.8 34.7 35.5 23.5 78 7O
ulwin 84.1 50.1 31.4 36.0 29.5 81 45
_ ultex 49.8 35.9 20.3
ustang 59.2 33.6 22.0
ew Nortex 84.6 55.7 33.0 35.6 23.5 74 45
orline 84.4 97.0 34.2 33.9 77 12
orwin 119.3 97.1 33.8 34.3 79 70
vpintok 109.9 78.9 52.8 35.1 33.4 36.9 24.3 83 37

~' mparable data based 0n years grown.
eck varieties used t0 compute comparable data.

I nd in Extension Districts 3, 4, 7, 8 and 10. The largest
i. reages of varieties grown are those of Ora, Moregrain
' d New Nortex. These three combined equal about 67
rcent of the State's acreage.

g As with barley, three growth-habit types of oats can
- and are grown in Texas. Although practically all
arieties will head even from spring seeding and do not
uire a period of vernalization in order to head normally,
ey vary greatly in seedling growth habit and cold
lerance. More complete descriptions of varietal character-
»ics are found in Texas Agricultural Experiment Station

ulletin 1091, "Growing Oats in Texas."

- all-Sown Performance Trials

l SEARCH AREA I: The High Plains area grows only about
‘ percent of the State's oat acreage. Oats are less cold

lerant than barley or wheat and even with the hardy

arieties now available, fall seeding is somewhat hazardous,
pecially if the crop is not irrigated.

p Performance trials have been conducted at Bushland
.- roughout the period, both from fall and spring seeding,
ables 20 and 32. Trials for shorter periods were con-
ucted at Etter, Plainview and Floydada, Table 21. Con-
'stent high yields have been produced by Norwin, Winter

cel, Cimarron, Dubois, Wintok and Bronco, and as these
e also the most cold tolerant, they are the safest varieties
p. grow. New Nortex, Mustang, Frazier and others have
reduced good yields, but they are less hardy and may be
Iled some years. Agronomic data are also given in Table
0. Data from the other locations are generally in agree-
ent with the Bushland data. ~

jESEARCl-I AREA II: Oats are grown extensively in this

ea. About 28 percent of the State's acreage is grown,
My d about half is harvested for grain. More than 18 per-
A t of the grain harvested is grown in Extension District

z Performance trials were conducted at Iowa Park until

965, with supplemental irrigation when needed, Table 22.
e best yields were produced by Ora, Cimarron, Norwin,

_ ubois and Mustang.

Trials were conducted at Chillicothe without irrigation
during the full period. Yields were much lower than at
Iowa Park, Table 23. The leading varieties were Norwin,
Alamo-X, Cimarron, Mustang and Wintok. Damage by
low temperatures occurred in 1959, 1962 and 1963. While
the very hardy varieties are less likely to be damaged by
low temperatures, the moderately hardy varieties such as
Ora, Alamo-X, Moregrain and New Nortex are widely
grown because of their forage characteristics.

RESEARCH AREA III: Extension District 4 grows about 15
percent of the State's acreage with about half harvested;
but, District 5 grows only about 2 percent with most of
it used exclusively for winter pasture. Extensive trials
were conducted at Denton, Table 24. The best compar-
able yields have been produced by Ora, Nora, Bronco,
Mustang and New Nortex. Victorgrain and Appler Rust-
proof have produced good yields but seed is not available.
A number of other varieties grown for short periods have
done well. At Overton, Coronado, Cortez, Ora and Hous-
ton all produced excellent yields. Agronomic data are also
given in Table 24. Cold tolerance is important, especially
in District 4, and important losses from low temperature
injury occurred in 1959, 1962 and 1963. However, in
most seasons the varieties of moderate hardiness will sur-
vive, and these usually are preferred because of their
desirable grazing characteristics. Lodging also is important
in this area. The varieties Ora, Moregrain, Alamo-X,
Bronco, Coronado and Cortez have much stronger straw
than New Nortex. Disease resistance is important in this
area in some seasons. Ora, Moregrain, Coronado and
Cortez have shown greater resistance to rust than others,
but there are new races of rust which will attack these
varieties.

Limited trials in connection with forage clippings were
conducted at Overton, Table 25. Variability was very
high, so no averages are given, but data indicate yield
potential in this area.

RESEARCH AREA IV: The Central Blackland, Prairie and
Cross Timbers land-use areas of District 8 grow about 23

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24

TABLE 25. ANNUAL YIELDS OF OAT VARIETIES GROWN
AT OVERTON OR MT. PLEASANT 1955-68

Yield of grain, bushels per acre

Variety 1955 1956 1967 1963 1964 1968
1 ew Nortex 18.8 31.6 46.1 62.1 46.4
Mustang 52.1 32.6 44.2 25.0 56.6
Bronco 57.6 58.6 52.5
Alamo 59.1 36.0 44.0 72.0 59.2
Alamo-X 70.2 88.2 82.7
Houston 52.8 104.5 93.5
Suregrain 62.5 75.9 88.8
Ora 114.1 94.9
*? oregrain 57.1 73.9 101.9
, “' lorida 500 88.4
(Cortez 97.0

oronado 1 09.3

percent of the State's acreage of oats and harvest about
40 percent of this acreage. About 3 percent is grown in
District 9 and 5 percent in District 11. Nearly all of this
is used for grazing. Less cold tolerant varieties can be
grown here, and owing to their more upright growth,
‘these are preferred for winter pasture.

. Performance trials were grown at Temple and Mc-
Gregor throughout the period. At McGregor, Table 26,
 e best comparable yields were made by Ora, Coronado,
A ortez, New Nortex, Nora, Florida 500 and Moregrain.
Ferguson 560 and Ranger are no longer available. The
leading varieties at Temple were New Nortex, Ora, Nora
a d Florida 500, Table 27. Radar I is no longer available.
Agronomic data are given in the same tables. Forage
estimates show that the more upright growing types were

evaluated as better for forage than New Nortex, the check
variety.

ESEARCH AREA V: Extension District 10 of South Texas

rows 13 percent of the States acreage but harvests only 6
ercent; District 12 grows 8 percent and harvests 14 per-
ent of that planted. Upright-growing, near spring-type
varieties can be grown. Even true spring-type varieties

rom the Mid-west can be fall-seeded, but these varieties

are damaged by livestock grazing more than others, so they
- e not used to any great etxent.

g Performance trials at College Station and Beeville are
given in Tables 28 and 29. Disease resistance, especially
resistance to the rusts, is an important factor in this area,
and yield data reflect this reaction. Coronado, Cortez,
Florida 501, Florida 500, Suregrain and Houston have
given much better grain yields than others, and they also
are among the best for winter pasture. Yields at Beeville

are much lower and reflect the lower, more erratic rainfall

of the area. Florida 501, Florida 500, Suregrain, More-

grain, Coronado and Cortez have produced the best grain

yields.

Spring-Sown Performance Trials

Spring-sown performance trials were grown only at
Denton, Chillicothe and Bushland. Data for Denton,

Table 30, show that Ora, Cortez, Coronado, Suregrain and

Moregrain have produced the highest yields. These also
have been the most rust resistant, an important factor in

yield of spring-sown oats, as the crop matures later than
fall-sown oats. Yields at Chillicothe, Table 31, have been
low. Actually the crop was almost a complete failure in
1966 and 1967. The highest comparable yields were
produced by Cortez, Neal (a spring-type variety from
Nebraska), Norwin, Cimarron, Moregrain and Suregrain.
Yields under irrigation at Bushland were high but less than
that of fall-sown oats under comparable conditions, Table
32. The varieties Ora, Norwin, Moregrain, Neal and
Suregrain produced the highest yields.

BARLEY

The barley acreage is considerably less than that of
wheat or oats, Table 1, and it fluctuates widely. During
the severe drouth years of the 1950's, it dropped to 45,000
acres, the lowest since 1918. The largest acreage ever
grown was in 1961 when 582,000 acres were seeded. An
increasing proportion of the crop is grazed to maturity.

Barley is nearly all fall-sown, and the acreage is widely
distributed over the State, Figure 5. A small acreage may
be spring-sown in Research Areas I and II in favorable
spring seasons or when the fall-sown crop is reduced by
winter injury. The acreages by extension districts and
research areas are given in Table 33.

Three types of barley are grown in Texas. They are
(1) winter type, (2) intermediate winter and (3) spring
type. Cold tolerant, winter-type varieties, such as Will
and Harrison, produce prostrate growing seedlings that
require a period of dormancy and cool weather (vernaliza-
tion) before they will head normally. The intermediate-
winter type varieties, such as Cordova and Era, are mod-
erately cold tolerant, yet they produce broad-leafed, mod-
erately upright growing seedlings that are well suited for
forage purposes. Spring-type varieties, such as Goliad and
Arivat, lack cold tolerance and produce seedlings with

   
 

BARLEY
ACRES PIANPED 196B

    

1 Dot = 1,000 Acres

  

Figure 5. Distribution of 1968 Texas seeded acreage of barley.

25

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TABLE 30. ANNUAL, AVERAGE AND COMPARABLE GRAIN YIELD OF SPRING-SOWN OAT VARIETIES 
DENTON, 1960-68‘ i‘

f

Comparable data’ " Yiejd of _  I
Test e1 i’ '
Number weight, Date Crown Plant Lodging, bush s per a
years pounds first rust, height, percent Actual t g

Variety tested per bushel head percent inches 2 years average
Frazier“ 7 31.2 5-1 29 31.0 75 "_.; 52.9
New Nortex” 7 27.0 5-9 20 27.5 24 49.4

Average 29.1 5-5 25 51.2
Alamo 4 28.2 5-5 25 28.8 24 47.1
Alamo-X 7 26.1 5-5 24 30.5 21 48.0
Cimarron 5 26.9 5-4 39 30.6 29 46.3
Clintland 64 4 30.5 5-13 8 33.4 33.9
Coronado 2 30.6 5-6 4 26.3 65.6
Cortez 1 30.1 5-3 60.3
Fulwin 2 27.4 5-6 39 32.8 28 51.4
Houston 6 28.9 5-4 1 1 24.8 42 50.1
Moregrain 6 29.9 5-4 24 27.2 15 51.8
Mustang 4 26.2 5-7 22 29.4 20 51.1
Neal 3 25.6 5-8 17 31.3 10 36.4
Norwin 5 27.6 5-5 29 28.1 40 51.9
Ora 3 31.6 5-3 1 22.8 4O 58.8
Suregrain 6 30.3 5-5 16 26.6 8 54.6
Tonka 3 32.0 5-5 30.3 35 40.8

‘No data for 1961 or 1968.
‘Comparable data computed from years grown.
"Check varieties used to compute comparable yields.

broad, upright growing leaves. This type can be fall-seeded RESEARCH AREA I: The High Plains area g
in South Texas or spring-seeded in Northwest Texas. 2O percent of the State’s barley acreage. h i?
More complete descriptions of barley varieties may be spring seeding is practiced, but usually fall-f
found in Texas Agricultural Experiment Station Bulletin produces higher yields and better quality grain i
1087, “Barley Production in Texas.” sown barley. Before cold tolerant varieties w

TABLE 31. COMPARABLE GRAIN YIELDS AND AGRONOMIC DATA FOR SPRING-SOWN OATS AT CHILLIC‘.
68 7

Yield of grain, bushels per acre Comparable agronomic data‘
Number Test
Average for years weight, Date
Variety years grown Comparable‘ grown pounds headed
Frazier’ 16.2 16.2 10 26.5 4-14
New Nortex” 13.4 13.4 10 24.3 4-21
Average 14.8 14.8 10 25.4
Alamo 17.6 12.9 3 24.9 4-16
Alamo-X 16.4 16.6 9 25.8 4-16
Cimarron , 17.1 17.3 9 27.5 4-15
Clintland 64 11.6 ~ 13.6 5 27.9 4-19
Coronado 8.4 16.3 3 29.6 4-17
Cortez 14.3 19.6 2 30.1 4-14
Florida 500 27.6 1 30.1
Houston 11.4 13.4 7 27.1
Moregrain 17.7 17.1 10 29.3 4-15
Mustang 18.6 16.3 6 26.1 4-16
Neal 13.9 19.5 3 28.1
Norwin 16 9 17.6 6 27.9 4-17
Ora 13.1 13.0 3 27.1 4-18
Surcgrain 13.8 16.7 6 29.1
Tonka 16.6 15.0 3 31.4
Victorgrain 13 7 12.3 1

‘Calculated comparable data based on years grown.
‘Check varieties used to compute comparable averages.

30

   
   

‘ -‘ 56-68

I BLE 52. GRAIN YIELDS AND AGRONOMIC DATA FOR SPRING-SOWN, IRRIGATED OAT VARIETIES AT BUSHLAND,

Yield of grain, bushels per acre

Comparable agronomic data‘

   
   
   
 
 
  
    

Number ' Test Plant Date

Average for years Comparable weight, height, first

ariety years grown grown average‘ pounds inches head

_ ' Nortex” 70.4 7 70.4 51.9 28.0 5-24

_zier’ 74.5 7 74.5 52.4 50.6 5-21
Average 72.4 7 72.4 52.1 29.5

m0 75.4 5 77.9 52.0 29.1 5-24

. o-X 74.6 6 75.5 50.6 28.4 5-24

' arron 82.9 6 77.9 52.7 28.6 5-22

_ intland 64 75.7 2 58.5 55.1 51.5 5-25
‘ ronado 1 55.7 29.8
rtez 1 51.6 29.8
1 rida 500 55.8 26.8

»; uston 76.6 5 69.8 55.8 24.8 5-24

,5 oregrain 84.7 5 81.9 54.5 27.4 5-22

ustang 68.8 5 75.4 51.0 29.1 5-22

cal 102.5 2 80.7 52.4 29.5 5-25

orwin 89.1 4 85.0 51.7 28.5 5-25
m 94.7 2 85.1 54.5 24.8

, egrain 81.9 4 79.2 52.5 27.1 5-20
1 66.8 56. 29.8

OHCH.

   

 

i lculated comparable data based on years grown.
A heck varieties used to compute comparable averages.

   
 
    
 
    
   
  
   
 

‘much greater proportion of the crop was spring-seeded
,an is now the case. Without irrigation, fall seeding in
. is area is still somewhat hazardous. Hail, shattering and
ynging are other hazards of production in Area I.

_ Performance trials of irrigated barley have been con-
ucted at Bushland for the full 10-year period, Table 54.
a rials for shorter periods were conducted at Etter and Plain-
’ iew, Table 55. The trials at Bushland were destroyed by
‘  in 1961 and 1965, and there was considerable damage
y low temperatures in 1962 and 1965. Diseases are not
 ually important in this area. Will barley has produced
a - tstanding yields and is resistant to the greenbug (aphid).

Wade, Zora and Rogers have performed well, but they are
less hardy than Will and may be damaged by low tempera-
tures. Chase, Harrison and Hudson are hardy and have
performed well. Results at Etter and Plainview were
similar to those at Bushland.

RESEARCH AREA II : Approximately 49 percent of the
State's barley acreage was grown in this area in 1968.
Winters are less severe here than in Area I; both winter
and intermediate-winter types can be grown. In the Trans-
Pecos, spring-type varieties were seeded in February after
the removal of crops of sorghum or cotton. Cordova,
Rogers and Will are the most popular commercial varieties.

' ABLE 55. ACREAGES AND PRODUCTION OF BARLEY BY EXTENSION DISTRICTS AND RESEARCH AREAS

  

Number of acres Percent of total

1 Research
{Extension testing Percent Production,
district area Land use area Seeded Harvested harvested Seeded Harvested bushels
1 I Northern High Plains 58,650 52,150 85 20.1 25.9 820,700
2 I Southern High Plains 8,990 6,200 69 4.7 6.0 180,500
5 II Low Rolling Plains 55,450 54,080 65 27.8 28.2 1,046,200
6_ II Trans-Pecos 10,750 6,450 60 5.6 5.2 159,750
7: II Rolling Plains and Edwards Plateau 28,950 18,760 68 15.1 15.1 455,400
4 III North Central Blacklands, Prairies 16,170 9,600 69 8.4 7.7 282,100
and Cross Timbers
5 III Northeast Timberlands 0 0
IV Central Blacklands, Prairies and 29,450 15,580 54 15.5 12.4 417,050
Cross Timbers
9 IV Central Blacklands, Prairies and 2,260 200 9 1.4 0.2
Timberlands
11 IV Upper Coast and Southeast 0
Timberlands
10 V South Central Blacklands, Prairies 2,750 200 7 1.4 0.2 2,900
and Coastal Bend
12 V Rio Grande Plain and South Texas 600 500 60 0.2 0.2 5,000
State Total 192,000 124,000 65 5,348,000

31

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32

ABLE 35. COMPARABLE YIELDS AND AGRONOMIC DATA FOR IRRIGATED. FALL-SOWN BARLEY VARIETIES GROWN

' T EITER AND PLAINVIEW, 1966-68

Yield of grain, bushels per acre

Comparable agronomic data‘

Etter Plainview Test weight, Plant
Number Com- Number Com- i-i-pounds per bushel  Hazlitt-mg
Actual Years parable Actual years parable Plain- _.i_
‘ ariety average grown average‘ average grown average‘ Etter view Plainview Etter
< soy 28.2 1 55.8 51.1 1 51.7 43.8 44.7 22
é St? 71.0 2 67.5 65.4 1 44.7 49.0 47.4 5-6
[d0Vi12 62.5 5 62.5 62.8 2 62.8 48.0 45.1 2s 5-3
8. 70.2 1 65.2 50.5
p arrison 83.0 1 80.5 57.5 2 57.5 46.3 48.9 27 5-6
udson 91.4 1 88.9 47.3 5-7
gets’ 67.8 3 67.8 55.4 2 55.4 46.6 47.4 29 5-7
nnessee Winter’ 52.6 3 52.6 43.6 1 43.6 44.7 47.7 23 5-5
kak 64.3 2 65.6 51.5 1 72.1 48.4 47.5 3O
ade 74.6 3 74.6 58.8 1 79.4 46.6 47.3 24 5-4
ill 78.6 3 78.6 67.1 2 67.1 47.3 46.3 30 5-5
ra 72.5 5 72.5 15.3 1 55-9 45.8 44.1 27 5-1

, lculated comparable data based on years grown.
eck varieties used in computing comparable data.

_ e majority of the barley is grown without irrigation,
cept in the Trans-Pecos.

Performance trials were conducted until 1965 under
ited irrigation conditions at Iowa Park, Table 36. Era,
ill and Rogers produced the best yields. At Chillicothe,
ble 37, the performance of Rogers has been outstanding.
ra, Harbine, Cordova, Era and Will also have performed
ell and are adapted to this area. Barsoy, Harrison and

gers have averaged highest in test weight and, are also

equately winter hardy for this area.

SEARCH AREA III: The North Central Texas and North-
t Timberlands areas produced about 11 percent of the
te's barley acreage in 1968. Cordova was the variety

V.» extensively grown. Performance data were obtained

i y at Denton, Table 38. At this location, Barsoy has
oduced outstanding yields for the last 3 years, and Zora

produced well over a 7-year period. Era, Will, Day-
- , Harrison and Rogers also have performed well at this
ation. Mildew, leaf rust and Helminthosporium leaf
i» are frequently important in this area. Harrison and
fferson showed the lowest rust infection, and several of
 varieties are resistant to mildew, but none of the adapted
- ieties are highly resistant to all the leaf spots, although
ere are some differences in reaction.

SEARCH AREA IV: Approximately 13 percent of the
te’,s barley acreage is grown in this area, most of it in
Pension District 8. Cold tolerance is less important in
's area than the preceding ones. Here disease resistance
more important.

The barley is used extensively for winter forage, and a
jority of the acreagéf is seeded to Cordova or other
l1 ediate-type varieties.

A Performance trials were conducted at Temple and
cGregor. At Temple, Tables 39 and 40, the highest
mparable yields were produced by Zora, Cordova and
ogers. At McGregor, Table 40, Zora, Rogers, Era,.Will

and Cordova produced the highest comparable yields,
Rogers, Zora, Florida 102 and Harrison produced grain
with the best test weight. Spring-type varieties were
injured by low temperatures in 1962 and 1963, but this
type of injury is rather infrequent. The spring-type varie-
ties Peruvian, Cebada Capa and Goliad were rated highest
in forage estimates.

RESEARCH AREA V: Only about 6 percent of the State's
barley acreage is seeded in this area, and the majority of
it is grazed to maturity. Diseases are important in grain
production, but low temperatures rarely injure barley.
Goliad, Cordova and Rogers are the principal varieties
grown commercially.

Performance trials were conducted at College Station
and Beeville. At College Station, Table 41, the highest
comparable yields, based on only 3 years’ tests, were pro-
duced by Florida 102 and Grande. Grande also produced
good yields. Grown for longer periods, Rogers, Will,
Cordova and Goliad have produced about equal yields.

At Beeville, Table 42, Florida 102, Grande and
Gainesville I have produced the best grain yields, although
most were tested only a short period. These varieties have
considerable tolerance to leaf rust and Helminthosporium,
important diseases of this area.

FL.AX

Flax is grown as a fall-sown crop only in Research
Area V. The distribution of the 1968 acreages is shown
in Figure 6. In recent years, the flax acreages have ranged
from a low of 17,000 acres in 1957 to 189,000 acres in
1963. However, in 1949, 329,000 acres of flax were
grown in Texas. Almost all of the crop was winterkilled
in 1962, and about 30 percent was lost in 1963.

Performance trials were conducted for the full period
only at College Station and Beeville, Tables 43 and 44.

33

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ests at Temple were conducted in 1958, 1959 and 1968,
able 45. Data for 1968 only were obtained at Robs-
wn. Agronomic data for College Station and Beeville
e given in Table 46.

Seedling disease and other factors caused poor stands
.1 several seasons. Cold tolerance is more important at
emple and College Station than at the other locations.
he most consistent high yields at these locations were
roduced by the winter-type varieties Mac, Dillman and
ldwell. These are the only ones that should be seeded
5 the southern Blacklands from San Antonio to Waco.
lthough comparable yields of Linda, Arny, Nored, Vik-
a » g and Norland were higher than the winter-type varieties,
.1 ey were tested in only a few seasons where winterkilling
id not occur. DeOro, a popular commercial variety, was
interkilled at College Station in both 1962 and 1963.

At Beeville, the highest comparable yields were pro-
uced by spring-type varieties grown for short periods.
hese included Dunes, Norland, Norstar, Nored and
inda. Among varieties grown for the full period, the
st yields were made by DeOro, B5128, Mac, Caldwell
d Dillman, but differences among these were small and
‘robably nonsignificant. DeOro was seriously damaged
y flax rust in 1966 and 1969, so growers are cautioned
.1 this hazard.

y Test weight differences among varieties were gen-
rally small. On the sandy soils at College Station, flax
loomed 1O to 15 days earlier than at Beeville. There

ABLE 43.
TATION, 1958-68‘

 

    

1 Dot = 1,000 acres

Figure 6. Distribution of 1968 Texas seeded acreage of flax.

were rather wide differences in blooming dates among
both winter and spring types. Very early northern varie-
ties, such as Arny, Windom and Bolley may be damaged
by spring freezes. The new winter hardy varieties Mac,
Dillman and Caldwell are shorter than most commercial

ANNUAL, AVERAGE AND COMPARABLE YIELDS OF FALL-SOWN FLAX VARIETIES GROWN AT COLLEGE

Yield of grain, bushels per acre

Average Number Com-
for years years parable

\1'3_fiety 1958 1959 1961 1962 1965 1964 1966 1967 grown grown average’
B51231 19,9 22.9 29.9 25.4 9.1 15.2 12.5 19.2 18.8 8 18.8
Caldwell“ 20.2 20.4 50.0 22.2 15.8 16.1 15.0 19.6 19.4 8 19.4
_i0“ 20.7 19.6 26.0 20.7 7.6 15.8 13.4 19.8 17.7 8 17.7
A Average 20.5 21.0 28.6 22.1 10.2 14.4 15.0 19.5 18.6 8 18.6
Arny 22.0 18.7 20-4 2 18-4
Bolley 21.4 15.5 13-5 2 16-5
Bonney Doon 16.5 16-5 1 15-6
‘gm 1.1 15.4 8.5 2 14.6
DeOro 17 9 24.5 27.6 0 0.8 12.5 8.5 17.9 15.8 9 15.8
Dillman 20 7 22.6 51.4 21.4 18.0 11.4 14.7 20.4 20.1 9 20.1
Dunes 20.5 20.5 1 19.4
Kamenlza 14.4 14.4 1 13.5
Linda 22.6 21.6 28.5 24.2 5 19.6
Mac 21.1 25.5 27.7 21.5 14.0 15.7 11.5 20.9 19.7 9 19.7
Marine 16.2 16-2 1 14-6
Newturk 10.8 15.5 29.1 25.0 14.6 10.8 12.9 18.1 16.8 9 16.8
Nor-aka   1 
Norland 21.2 20.5 20-9 2 18-9
Nomad 21.4 21.4 1 20.5
Nod-Star 6.5   2 
Redwood 22.2 22.5 26.6 21.1 5.5 15.5 7.5 19.0 17.1 9 17.1
‘Viking 18.5 20.9 25.4 21.6 3 16.9
windom 0 0 4.4 18.1 5.6 4 8.1
115D ._ 5 percent 4.7 4.8 3.8 2.4 5.1 NS

 

‘No data for 1960, 1965 and 1968 because of poor stands, seedling disease, etc.
‘Comparable average based on years grown.
‘Check varieties used to compute comparable averages.

41

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42

.TABLE 45. ANNUAL AND AVERAGE YIELDS AND AGRONOMIC DATA FOR FALL-SOWN FLAX AT TEMPLE AND
ROBSTOWN, 1958-68

TempIle Robstown
Yield of grain, bushels Test welght: wlnter _ _
pounds lfljllfy Grain yield,
Variety 1958 1959 1968 1968 1968‘ bushels
Amy 13.4 7.2
B5128 16.3 10.7 12.0 55.9 2.0 9.2
Bolley 8.9 0 i
Bonny Doon 10.5 56.5 3 2 1O 7
Caldwell 15.2 9.8
Caldwell 32 11.8 56.7 1.8 9.3
fDeOro 13.0 8.7 12.1 54.6 3.5 9.6
’Dillman 17.0 11.9 14.3 55.4 1.7 7.6
Dunes 8.2 55.8 4.0 10.1
Kamaniza 11.2 55.8 3.5 11.0
"Linda 13.6 8.9
iLinnott 11.1 55.0 2.5 10.1
Linore 10.6 56.1 1.0 6.3
Mac 18.2 10.2 15.1 54.5 1.5 8.1
_Newturk 17.4 10.4 11.7 56.2 1.2 8.7
Noralta 12.2 56.2 2.3 8.2
Nored 12 5 56.5 3.3 11.3
A Norland 19.3 9.1
Norstar . 9.1 55.4 2.8 9.0
RedWOOd 11.4 7.2 11.2 56.0 2.7 8.7
Rio 14.2 8.2 1O 4 56.1 2.0 8.9
Viking 14.6 11.6
Windom 8.0 56.0 3.8 8.3

C‘Rated one to five with five plants killed.

TABLE 46. COMPARABLE AGRONOMIC DATA FOR FALL-SOWN FLAX VARIETIES AT COLLEGE STATION AND BEE-
VILLE, 1958-68

Test weight,
poun Percent survival Pasmo
per bushel Date first bloom 1962 and 1963 score“
College College College College College Percent Iodine
Variety Station Beeville Station Beeville Station Beeville Station Beeville Station oil value‘
1351282 53.4 52.5 3-10 3-27 27.3 25.6 55 66 2.0 38.3 171
Caldwellfl 53.9 53.6 3-13 5-27 26.0 21.6 78 86 2.2 56.5 169
R102 53.8 52.4 2-27 3-21 26.8 23.6 53 79 1.8 38.1 172
Average 53.7 52.8 26.7 23.6
I Amy 54.6 51.2 3~1 3-21 25.0 24.8
Bolley 55.6 51.8 2-12 5-17 24.0 20.6
y Bonney Doone 53.2 51.7 3-2 3-19 25.7 24.6 4.7
Caldwell 32 53.7 52.0 3~12 3-26 21.1 2.8 36.4 167
Cree 55.6 52.5 3-17 27.0 25.0 1 80
DeOIO 53.3 52.3 3-7 3-22 27.0 24.4 2 61 4.0 38.3 177
Dillman 53.9 52.6 3-6 3~22 21.8 20.4 91 84 2.7 37.8 176
Dunes 53.7 51.7 3-1 3-15 20.7 18.6 6.0 41.9 169
Kameniza 52.2 51.7 3-1 3-14 23.7 23.6 6.3 36.7 172
Linda 52.8 51.8 2-26 3-19 26.2 24.2
Linore 52.0 50.8 3-7 3-23 25.8 20.6 86 83 2.3 36.4 168
Mac; 53.7 51.3 3-5 3-22 22.3 20.9 83 86 3.7 37.5 176
Marine 53.7
_ Newturk 53.3 53.3 3-14 3-31 25.8 21.5 87 85 2.3 40.0 168
Noralta 52.7 49.5 2-28 3-18 23.3
Norland 53.1 53.3 3-13 4-2 29.0 29.6
Nored 54.2 50.3 3-3 3-21 22.7 24.9 2.3 39.3 179
Norstar 53.7 51.1 3-3 3-18 24.7 26.0 3.3 38.5 173
Redwood 54.3 53.0 2-26 3-19 24.3 23.1 6 70 1 7 37.9 177
Viking 53.0 51.6 3-4 3-24 27.2 25.0
Windom 51.9 50.1 3-3 3-17 26.7 23.1 0 30 2.0 37.8 178

‘Comparable data based on years grown.

‘Check varieties used to compute comparable data.
“Rated one to 10 with 1O high infection and damage.
‘Average of College Station and Beeville for 1967.

w

43

varieties and sometimes criticized for being too short to
harvest easily. The winter-type varieties were more cold
tolerant than spring-type varieties. B5128 and Rio have
more cold tolerance than most other spring varieties. The
seed of Dunes and Newturk were the highest in oil con-
tent while Caldwell and Linore were among the lowest
in oil.

ACKNOW/LEDGMENTS

These investigations were conducted cooperatively by
the Texas A&M University Agricultural Experiment Sta-
tion and the Crops Research Division, Agricultural Re-
search Service, U.S. Department of Agriculture.

Acknowledgment is made to the following people
and agencies taking part in the statewide small grains and
flax performance trials.

Soil and Crop Sciences Department, Texas A8cM Uni-
versity Agricultural Experiment Station, College Station:
O. G. Merkle, research agronomist, Crops Research Divi-
sion, Agricultural Research Service, U.S. Department of
Agriculture; Paul E. Pawlisch, formerly assistant professor,
M. E. McDaniel, assistant professor, and Earl C. Gilmore,
]r., assistant professor.

Field Units: Lucas Reyes and Edward Neal, Texas
A&M University Agricultural Research Station at Beeville;
Eldon D. Cook, U. D. Havelka and Ralph Baird, Black-

44

  
  
   
   
 
   
  
  
  
  
 
   
   
 
  
   
   
  

land Research Center, Temple; J. H. Garden.
Eugene Wilkerson, Texas A8zM University A y
Research Station at Denton; Keith A. Lahr . l
Mulkey, Texas A&M University Agricultural v
Station at Chillicothe; Virgil Woodfin, Texas 4,
versity Agricultural Research Station at Iowa Par

Smith and john C. Williams, Texas A&M p
Prairie View Experiment Station, Prairie View};
Norris and H. O. Hill, Texas "A8zM University A y
Research Center at McGregor;  A. Lancaster and“?
Texas A8zM University Agricultural Research i 
sion Center at Overton; and K. B. Porter, T. G.M
Wayne Cooley, Charles Cowley and Orrell V1
Southwestern Great Plains Research Center at I

Off-station performance trials were conduct{
through the cooperation of john Shipley and Ci i
at Plainview by B. M. Hughes; at Stratford 
Sneed; at Perryton by Harlan Hawk, Delbert T‘ n,
Douglas Smith; at Wellington by Dwayne Scott '
Baumgardner and at Hartley by Bruce Thompsong
L. Dysart. a -*

Assistance in insect observations were made - ,~
E. Daniels. Assistance in disease observations 
by Robert W. Toler, pathologist, Department I
Sciences and R. A. Kilpatrick, and Francis Gough,‘
Plant Pathologists, Crops Research Division, y;
Research Service, U. S. Department of Agricul 
ville, Maryland, and College Station, Texas,