BULLETIN 383 OCTOBER 1968

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ZOYSIA AND TIFLAWN BERMUDAGRASSES
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Agricultural Experiment Station AUBURN UNIVERSITY
E. V. Smith, Director Auburn, Alabama

CONTENTS

Page EXPERIMENTAL METHODS

RESULTS Effect of Soil Type and Grass Species on Yield Effect of P on Yield and Mineral Content of Clippings Effect of P on Appearance and Earliness Effect of K on Yield and Mineral Content of Clippings Effect of K on Appearance and Earliness Effects o f L im e . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. Effects of Lime on Ca, Mg, P, and K Content Soil T est Relationships PLATE 1 PLATE 2 SUMMARY AND CONCLUSIONS LITERATURE CITED ............................

5__ 5
6 8

9
11 _14 15

_15
_12 _13 _19 _21

COVER PHOTO. Cover shows overall view of one series of the turf research plots.

FIRST PRINTING 4M, OCTOBER 1968

Phoftodj/auasst dPoads~iam

ors

ZOYSIA and TIFLAWN BERMUDAGRASSES

aa

qlo

Soil Tlprt

D. G. STURKIE, Professor Emeritus of Soils R. D. ROUSE,' Assoc. Director and Asst. Dean, Agricultural Experiment Station and School of Agriculture

Z

oysia (Zoysia matrella, L, Merr.) and bermuda are the two most extensively used grasses on lawns in Alabama. Bermudagrass (Cynodon dactylon, L, Pers.) is also used extensively on playgrounds, athletic fields, and golf course tees, fairways, and greens. Fertilizer practices for these grasses vary considerably. Research has produced much information relating soil tests to fertilizer needs of field and pasture crops, but very little similar information is available on turf for landscapes and recreational areas. Also, information on relation of soil type to turf growth and response to fertilizer practices is lacking. Some information is available on relation of plant analysis to fertilizer response in turf. Much information on turf fertilization is based on hay or pasture type turf where the main consideration is on growth and yield rather than on appearance. Appearance is of much more importance for lawns and other turf areas than is vegetative growth. A study was begun at Auburn in 1959 to obtain information on influence of soil type and fertilizer practices on growth, mineral composition, and appearance of turf and soil test values. This report gives results of this study for the 6-year period 1961-66, inclusive.
1

Formerly Professor of Soils in charge of Soil Testing.

4

ALABAMA AGRICULTURAL

EXPERIMENT STATION

EXPERIMENTAL METHODS A study to determine the P, K, and lime requirements of zoysia matrella P.I. No. 13521 and Tiflawn (Tifton 57) bermuda was conducted at Auburn on four soil types-Decatur clay loam, Hartsells fine sandy loam, Norfolk sandy loam, and Norfolk fine sandy loam. The soil was placed in 18-inch deep concrete bins with steel partitions several years prior to the study. Each bin was 8.5 feet square. The initial fertilizer and lime treatments were applied and mixed with the top 6 inches of soil. Subsequent treatments were applied on the surface. Water was applied as often as needed to keep the plants growing vigorously. The treatments were in duplicate on each of the soil types and on each grass. Results are for the average of the duplicates. Ammonium nitrate was applied to all treatments at an annual rate of 400 pounds N per acre. Phosphorus and potassium rates varied. Normal 20 per cent super phosphate (9 per cent P) was used to supply P, and 60 per cent muriate of potash (50 per cent K) was used to supply K. One-half of the P and K was applied in the spring before growth began and the other half in the fall, about October 1. Nitrogen at the rate of 60 pounds N per acre was applied in the fall and spring at the time of application of P and K. Nitrogen at the rate of 70 pounds per acre was applied approximately May 1, June 1, July 1, and August 1. Lime (dolomite) was added to bring the pH to about 6.5 on the treatments designated to study rates of P and K. Lime was added annually as needed to maintain the pH at about 6.5 except on the treatment for studying the effect of lime. The grasses were set in the spring of 1959 and were allowed to grow with an occasional mowing until established. Before growth began in the spring of 1960, all dead vegetation was removed to t e soil surface. Clipping treatments were begun in the spring of 1 ij0 and records begun in 1961. The grass was clipped at a height of 1 inch as often as needed (usually every 2 weeks). The clippir gs from each plot were removed, oven dried, and weighed. Plant sa mples for analysis were taken on three dates (approximately May 10, July 10, and September 1). Plant samples were taken on the second cutting following N applications. Analysis was made for P, K, Ca, and Mg. Soil samples were taken at 0-2- and 2-6-inch depths initially and each year before growth started in the spring. Determinations by the methods of Page et. al (10) were made for P, K, Mg, pH, and for lime requirement.

ZOYSIA AND TIFLAWN

BERMUDA

5

Ratings based on appearance were made several times each year. These usually were made to determine earliness, color, and general appearance. Clipping weights were recorded as a measure of vigor. Density and ground cover were not measured independent of appearance. RESULTS
Effect of Soil Type and Grass Species on Yield

Yields of bermuda and zoysia on each of four soils from various applications of P, K, and lime are shown in Tables 1, 5, and 9. The difference in yields was greatest when no P or K was applied. There was a large difference in the yields of no P and no K treatment among soils. The Hartsells fine sandy loam and the Norfolk fine sandy loam produced lower yields than did Decatur clay loam or Norfolk sandy loam. There was little difference in maximum yield on the various soils; thus, the increases in yields from treatments were greatest on Hartsells and Norfolk fine sandy loam soils.
TABLE 1. AVERAGE TOTAL YIELDS OF DRY MATTER PER ACRE WHEN VARIOUS 1 RATES OF P WERE APPLIED TO ZOYSIA AND BERMUDA ON FOUR SoILs

P applied 2
annually,

lb. per acre
Decatur clay

Average annual yield, dry matter per acre Bermudagrass Zoysiagrass 1961-63 1964-66 Av. 1961-63 1964-66 Lb. Lb. Lb. Lb. Lb. 4,104 7,806 9,126 9,258 3,126 7,476 9,528 9,498 3,528 7,572 8,988 8,778 2,010 7,062 9,642 9,984 5,313 8,616 9,339 9,582 3,402 7,896 9,291 9,417 7,956 10,032 10,212 10,116 5,124 9,150 .9,504 9,744 7,506 9,630 10,392 10,050 4,698 9,600 10,602 10,650
2 5

Av. Lb. 7,062 10,209 10,617 10,419 5,352 9,603 9,867 10,110 6,519 9,060 9,690 9,489 5,169 9,474 10,968 10,884

0

6,522 9,426 9,552 44 88 9,906 Hartsells fine sandy loam 0 3,678 22 8,316 44 9,054 88 9,336 Norfolk sandy loam 0 6,126 22 8,622 44 8,766 88 9,558 Norfolk fine sandy loam 0 2,688 22 7,596 44 9,576 9,630 88 22

6,168 10,386 11,022 10,722 5,580 10,056 10,230 10,476 5,532 8,490 8,988 8,928 5,640 9,348 11,334 11,118

4,827
8,097 8,877 9,168 2,349 7,329 9,609 9,807

'2Ratesrate of equivalent was0,166 lb. perand 200 lb.dolomite was addedrespectively. The of P K applied to 50, 100 acre and of P 0 per acre as needed.

6

ALABAMA AGRICULTURAL EXPERIMENT STATION

Effect of Phosphorus on Yield and Mineral Content of Clippings

Both grasses produced near maximum yields at the 44-pound rate of P (100 pounds P205 ) on all four soils, Table 1. The largest response per unit of P was from the first 22 pounds. The response from 44 pounds over 22 pounds was relatively small with no appreciable difference in yield for 88 pounds over 44 pounds. These rates are much below those of Juska (5) (6) for Kentucky bluegrass. Bermuda gave greater response to P than did zoysia. Yields of bermuda on the 0- and 22-pound P plots decreased in the second 3-year period. Bermuda responded to 44 pounds P (100 pounds P 205 ) on all four soils. Zoysia needed only 22 pounds P (50 pounds P2 05 ) on the Decatur and Hartsells soils, but responded to 44 pounds P (100 pounds P205 ) on the Norfolk soils. Need for P would be expected to have been less in all cases at a rate of N lower than the 400 pounds applied to these plots. These results indicate that many turf areas receive recommendations for a higher rate of P than is needed for growth.
TABLE 2.
2

AVERAGE P CONTENT OF DRY MATTER WHEN VARIOUS RATES OF P WERE APPLIED TO ZOYSIA AND BERMUDA ON FOUR SOILS'

P applied annually, lb. per acre

P content of dry matter Zoysiagrass Bermudagrass 1964-66 1961-63 Av. 1964-66 1961-63 Pct. Pct. Pct. Pct. Pct. 0.15 .22 .29 .35 .14 .21 .30 .38 .13 .21 .29 .34 .13 .20 .27 .34 0.16 .24 .30 35 .14 .21 .30 .36 .12 .21 .29 .33 .12 .19 .27 .33 0.14 .21 .27 .33 .11 .18 .27 .34 .16 .24 .28 .32 .11 .16 .25 .32 0.13 .19 .29 .36 .12 .18 .28 .33 .13 .24 .82 .39 .12 .19 .29 .38

Av. Pct. 0.13 .20 .28 .35 .11 .18 .27 .34 .14 .24 .30 .36 .11 .17 .27 .35

Decatur clay 0.18 0 ---.26 -----22 ..... .30 44 .35 88 Hartsells fine sandy loam .14 0 .21 22 .30 44 .35 88 Norfolk sandy loam .12 0 .20 22.29 44 .31 88 Norfolk fine sandy loam .11 0 .18 22 .27 44 .31 88

iThe 2

rate of K applied was 166 lb. per acre and dolomite was added as needed. Rates of P equivalent to 0, 50, 100 and 200 lb. of P 205 per acre respectively.

ZOYSIA AND TIFLAWN BERMUDA

7

Applications of P increased the P content of clippings, Table 2. Bermuda and zoysia were similar in P content, although at deficient levels zoysia usually contained a slightly lower percentage P. The critical level of P was about 0.2 per cent for these grasses. Above 0.3 per cent there was little or no growth response, while below 0.2 per cent there was a definite response to P. These figures agree with those of Lunt (7) and Ferguson (3) but are higher than those of Oertli (9). These results, considered together with a higher yield of zoysia than bermuda at zero P, show that zoysia has a lower P requirement than bermuda. The amount of P removed in the clippings from the larger yielding plots was about 30 pounds per acre. Applications of P increased the K content of both grasses, Table 3, and the K content of both grasses was similar on all soils. These results were from treatments that had received the highest rate of K and therefore should not be regarded as indicating an improvement in the efficiency of K utilization. Applications of P increased the calcium content of bermuda but had no effect on the calcium content of zoysia. The type of soil had no effect on calcium content. These results were obtained from treatTABLE 3. EFFECT OF PHOSPHORUS APPLICATIONS ON AVERAGE K, CA, AND 1 CONTENT OF DRY MATTER OF CLIPPINGS ON FOUR SOILS MG

P applied2 annually, lb. per acre
Decatur clay

K Pct. 1.20

K, Ca, and Mg content of dry matter Zoysiagrass Bermudagrass Ca Mg K Ca Pct. Pct. Pct. Pct. 0.42 0.17 1.28 0.85

Mg Pct. 0.18

0

22

1.86

.46
.50 .48

.16
.19 .18

1.30
1.40 1.42

.34
.35 .34

.18
.18 .18

1.42 44 1.40 88 Hartsells fine sandy loam

0
22 44 -88 Norfolk sandy loam
0 ----.

1.08
1.26 1.35 1.24
95

.44
.43 .52 .50
.41

.17
.18 .18 .18 .16

1.18
1.39 1.35 1.37 1.16

.34
.36 .36 .38 .40

.17
.19 .18 .19
.18

22__ 44
88

1.22 1.35
1.27

.46 .47
.54 .42

.17 .18
.19 .17

1.36 1.30
1.34 1.12

.37 .37
.37 .35

.20 .18
.16 .17

Norfolk fine sandy loam .98 0

1.27 22... 44_............... 1.36
88 1.37

.48 .48
.51

.17 .17
.19

1.40 1.36
1.36

.33 .33
.34

.16 .20
.19

'The rate of K applied was 166 lb. per acre and dolomite was added as needed. 2 Rates of P equivalent to 0, 50, 100 and 200 lb. of P2 05 per acre respectively.

8

ALABAMA AGRICULTURAL EXPERIMENT STATION

ments that had dolomitic limestone added as needed to maintain soil pH. Applications of P had little or no effect on magnesium content of either zoysia or bermuda. Neither did soil type affect magnesium content. These results were obtained from treatments that had dolomite as needed to maintain the pH near 6.5; therefore there was an abundant supply of magnesium.
Effect of Phosphorus on Appearance and Earliness

The appearance ratings, Table 4, showed some decrease in appearance of bermuda when no P was applied. Over the years studied the 22-pound rate produced as good an appearance as any other rate. Quite often the bermuda on the high P rate was lighter green in color than that on the low rate. The bermuda on the no P treatments had a dwarfed, stunted appearance and a reddish-purple cast.
TABLE 4.

THE EFFECT OF P APPLICATIONS ON APPEARANCE AND EARLINESS OF
BERMUDA AND ZOYSIA
1

P applied annually, lb. per acre

2 Average annual rating Zoysiagrass Bermudagrass 1967 Av. 1965 1966 1966 1967 1965

Av.

0------------------------------22---44--.--------------------------------88------

8
9 8 9 4

Appearance in the growing season 8 10 6 7 8
9 9 10 4 9 9 9 7 9 9 9 5 8 6 6 6 9 10 8 7

8
9 9 6 6

9
9 8 7 6

Earliness in the spring 0 -22 44 88
1
2

10 10 10

9 9 9

8 8 8

9 9 9

9 8 7

9 9 7

9 8 8

9 8 7

The rate of K applied was 166 lb. per acre and dolomite was added as needed.
Rating was done several times each year by 2 or more persons when differences the year. 10=best, 1=poorest.

were apparent. Results reported are averages for four soils for all ratings during

Zoysia had a good color in the no P treatments but the plants were dwarfed. These symptoms of P deficiency are in agreement with those described by Morgan (8). The high P treatments produced zoysia that was lighter green and often plants became chlorotic. The colors shaded from dark green to yellowish green as the P treatments went from 0 to 88 pounds per acre. The chlorotic condition could be corrected by spraying with a soluble iron compound such as ferrous sulfate. Therefore, it is assumed that the excess P was producing iron deficiency in zoysia. Bermuda was not sensitive to high P.

ZOYSIA AND TIFLAWN BERMUDA

9

Earliness of zoysia and bermuda was affected by P applications. Plants not receiving P were later emerging in the spring. The amount of P applied made little or no difference in earliness of bermudagrass. The 22-pound rate began growth just as early as did the 88-pound rate. As the rate of P increased, early growth of Zoysia was delayed. Effect of Potassium on Yield and Mineral Content of Clippings Yields of both grasses were increased by K on all soils, Table 5. Zoysia produced higher yields than bermuda at all rates of K. The differences were greatest at the zero application and bermuda gave
TABLE 5. AVERAGE TOTAL YIELDS OF DRY MATTER PER AcRE RATES OF K- WERE APPLIED TO ZOYSIA AND BERMUDA ON

FOUR

WHEN VARIOUS 1 SOILS

K applied annually, 2 lb. per acre

Average annual yield, dry matter per acre Zoysiagrass Bermudagrass 1964-66 1961-63 Av. 1961-63 1964-66 Lb. Lb. Lb. Lb. Lb. 6,141 8,802 9,273 9,582 4,551 8,208 9,153 9,417 9,858 10,380 10,146 10,116 8,436 9,780 9,480 9,744
8,862

Av. Lb. 8,058 10,053 10,829 10,419 6,714 9,981 9,705 10,110
6,720

Decatur clay 4,014 8,268 0 ________________________________ 7,920 9,684 42________________________________ 8,922 9,624 83________________________________ 9,258 9,906 166______________________________ Hartsells fine sandy loam 2,640 6,462 0 ________ 7,668 8,748 42________________________________ 8,946 9,360 83________________________________ 9,498 9,336 166______________________________ Norfolk sandy loam 3,930 7,470 0 7,098 8,892 42______________________________ 8,598 9,198 83________________ 8,778 9,558 166________________ Norfolk fine sandy loam
0

6,258 9,726 10,512 10,722 4,992 10,182 9,930 10,476
4,578

5,700 ------------------------------7,596 9,558 7,995 8,898 9,168 10,212 10,050
8,622

8,598 8,928
3,984

8,577 9,405 9,489
6,303

9,948 8,238 7,554 8,922 42________________ 10,548 9,330 8,580 83________________ 10,080 10,650 9,807 9,984 166_______________ 9,630 1 The rate of P applied was 88 lb. per acre and dolomite was 2 Rates of K equivalent to 0, 50, 100 and 200 lb. of K2 0 per

----------------

6,882

3,762

5,322

9,042 10.464 11,118

9,495 10,506 10,884

added as needed. acre respectively.

greater response to K than did zoysia. Most of the, response was produced by the first 42 pounds of K. Increase in yield from the 166-pound rate over 83 pounds was small. Response to K was greater
in the second 3-year period than in the
.first

because

yields -dropped

on the 0 K plots. Response to K was much less on. the Decatur clay than on the other three more sandy soils. Application of 42 pounds of K (50 pounds K20) was adequate for zoysia on Decatur and Hartsells, but 83 pounds K -(100 pounds K20) was needed on the

10

ALABAMA

AGRICULTURAL

EXPERIMENT

STATION

10

ALABAMA AGRICULTRLEPRMN

TTO

two Norfolk soils. Bermuda gave a good growth response to 83 pounds of K (100 pounds K20) on all soils. The amount of K removed in the clippings from the higher yielding plots was about 100 pounds per acre (10,000 pounds at 1 per cent K). The application of K at the high rate of P and lime increased the K content of bermuda and zoysia, Table 6. Both grasses were similar in K content on all soils. The critical K content of these plants was approximately 1.0 per cent. Below this figure there was a definite response to K applications, but above this there was little response. These results are slightly lower than those of Ferguson (3) but are higher than those of Oertli (9).
TABLE 6. AVERAGE K CONTENT OF DRY MATTER WHEN VARIOUS 1 WERE APPLIED TO ZOYSIA AND BERMUDA ON FOUR SOILs

RATES

OF K

K applied annually, 2 lb. per acre

K content of dry matter Zoysiagrass Bermudagrass 1961-63 1964-66 Av. 1961-63 1964-66 Pct. Pct. Pct. Pct. Pct. 0.44
-------------------------

Av. Pct. 0.51 .74 1.01 1.42 .34 .64 .94 1.37 .43 .66 .95 1.34
.34

Decatur clay o -------------------------------- 0.67
42 --

.92

83---------------------- ----------1.14 166------------------------------ 1.33 Hartsells fine sandy loam 0 -------------------------------- .48 .76 42-------------------------------83------------------------------ 1.05 166------------------------------ 1.10 Norfolk sandy loam 0 -----------------------.57 42 --------------- .81 83----------------------- 1.10 166---------------- 1.17 Norfolk fine sandy loam 054 .74 42---------------.92 83---------------166---------------- 1.23

1.08 1.46 .41 .68 1.01 1.38 53 .83 1.03 1.37

.79

0.56 .85 1.11 1.40 .44 .72 1.03 1.24 .55 .82 1.07 1.27
.47

0.65 .83 1.05 1.38 .43 .71 .99 1.29 .52 .68 1.01 1.26
.38

0.37 .64 .97 1.46 .25 .56 .89 1.45 .34 .64 .88 1.43
.30

.39 .73
1.00 1.51

'The rate of P applied was 88 lb. per acre and dolomite was added as needed. K equivalent to 0, 50, 100 and 200 lb. of K20 per acre respectively. 'Rates

increased the P content of zoysia and bermuda, The application Table 7. This is probably associated with the unthrifty condition of the grasses on the -zero K treatment. did not greatly affect the calcium content, The application of Table 7. Bermudagrass was higher in Ca content than zoysia, but there were no differences between soils. Fertilization with, K decreased the Mg content of both grasses, Table 7. This was most pronounced at' the high rate of K.

-of of XC
K

.74 .96 1.37

.71 .91 1.32

.52 .79 1.40

.62 .85 1.36

ZOYSIA

AND

TIFLAWN

BERMUDA

11

TABLE

7.

AVERAGE

P, CA,

RATES OF

K

WERE

AND MG CONTENT OF DRY MATTER WHEN VARIOUS 1 APPLIED TO ZOYSIA AND BERMUDA ON FOUR SOILs

K applied 2 annually, lb. per acre

P

P, Ca, and Mg of dry matter Zoysiagrass Bermudagrass Ca Mg P Ca

Mg

Pct.

Pct.

Pct.
0.24 .24 .22 .18 .26 .24 .22

Pct.
0.31 .33 .34 .35 .32 .34 .35

Pct.
0.41 .40 .36 .34 .41 .41 .40

Pct.
0.22 .20 .19 .18 .25 .21 .20

Decatur clay 0.48 0 --............................. 0.30 .46 .33 42________________________________ .49 .37 83 .35 166______________________________.48 Hartsells fine sandy loam .45 0 ---------------- 29 .32 .46 42 .48 .35 83

166

.36

.50

.18
.24 .23 .21 .19 .24 .24

.34
.33 .35 .37 .36 .31 .35

.38
.44 .42 .44 .37 .42 .38

.19
.23 .21 .22 .16 .24 .21

Norfolk sandy loam .29 .48 0 .49 .32 42 .48 .34 83 .33 .54 166 Norfolk fine sandy loam .28 .43 0 .32 42_______________________________.43

.47 .34 83 ____________________________ .51 .33 166_
2

.25 .19

.35 .35

.38 .34

.19 .19

'The rate of P applied was 88 lb. per acre and dolomite was added as needed. Rates of K equivalent to 0, 50, 100 and 200 lb. of K20 per acre respectively. Effect of Potassium on Appearance and Earliness

The appearance ratings, Table 8, show a poor appearance for treatments receiving no K. This was true for both zoysia and bermuda. The low rate of K (41.5 pounds per acre) produced plants with less desirable color than did the medium rate (83 pounds) or the high rate (166 pounds). The plants without K showed typical K deficiency symptoms. The plants were dwarfed, grew slowly, were light green in color, the tips of leaves often died, and the turf appeared dry. Often the plants appeared as if they were suffering from drouth. The deficiency symptoms were similar to those described by Morgan (8). The initiation of plant growth in the spring was about 2 weeks later on the no K treatments than on those receiving K. A deficiency of K often resulted in winter kill of bermuda during winters of unusually low temperatures. No diseases were prevalent during the studies. Goss (4) has shown K applications reduce the incidence of diseases in turf grasses. Evans (2) found less leafspot present on Coastal bermuda that received high K rates.

ALABAMA AGRICULTURAL

EXPERIMENT

STATION

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PLATE 1. Tiflawn plots in April show browning or rusting typical of K deficiency (top) ond sparse early growth caused by P deficiency (center) compared to vigorous green growth from adequote fertilizer.

ZOYSIA AND TIFLAWN BERMUDA

a4

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14

ALABAMA

AGRICULTURAL

EXPERIMENT

STATION

14
TABLE

ALABAMA AGRICUTRLEPIMNSAIO

8.

THE EFFECT OF

K

APPLICATIONS ON APPEARANCE BERMUDA AND ZOYSIA'

AND EARLINESS

OF

K applied annually, lb. per acre

1965

Average annual rating 2 Zoysiagrass Bermudagrass 1966 1967 Av. 1965 1966 1967 Appearance in the growing season 9 9 10

Av.

o--------------1

42----------------------------- - 6 83------------------------- 7 166 ------------------------------ 7

1

6 7 7 7 8 9 8 6 9 9 9 6 Earliness in the spring
1 1

1

1

3

2

1
7 8 7
1

2
7 7
1

7

1 1 2 1 0 ----------------------------

7 7 7 6 8 6 5 42-------------------------------- 7 8 8 8 8 9 9 9 83------------------------------- 10 8 7 7 7 8 9 9 10 166-------------'The rate of P applied was 88 lb. per acre and dolomite was added as needed. 2 Rating was done several times each year by 2 or more persons when differences were apparent. Results reported are averages for four soils for all ratings during the year. 10=best, 1=poorest. Effects of Lime

Application of lime to maintain pH between 6.0 and 6.5 had little or no effect on the yield of bermudagrass on any of the 4 soils tested, Table 9. The yield of zoysia was increased slightly on two of the soils (Norfolk sandy loam and Norfolk fine sandy loam) by application
TABLE 9. THE EFFECT OF LIME ON AVERAGE TOTAL YIELDS OF DRY 1 PER ACRE ON ZOYSIA AND BERMUDA ON FOUR.SOILS MATTER

Lime application

Average annual yield, dry mattter per acre Zoysiagrass Bermudagrass 1964-66 1961-63 Av. 1961-63 1964-66 Lb. Lb. Lb. Lb. Lb. 9,258 10,020 9,498 9,678 8,778 8,970
9,984

Av. Lb. 10,419 11,058 10,110 10,044 9,489 8,337
10,884

Decatur clay2 as needed ------- 9,906 none ----------------- 10,080 Hartsells fine sandy loam as needed 2 ------- 9,336 none ------------ 9,372 Norfolk sandy - -loamas needed 2- - - - -9,558 none -------------- 9,540 sandy Norfolk fine2------- loam
as

9,582 10,050 9,417 9,525 9,168 9,255
9,807

10,116 11,274 9,744 9,852 10,050 9,120
10,650

10,722 10,842 10,476 10,236 8,928 7,554
11,118

none -------------'The 2

needed

-9,630 9,972

9,366

9,669

9,654

8,340

8,997

rate of P applied was 88 lb. and of K was 166 lb. per acre. To maintain pH at near 6.5.

of lime but was not affected on the other two soils. The average annual pH of the soil is shown in Table 10. Soil pH was maintained near 6.5 by applying lime annually as the need was

ZOYSIA

AND

TIFLAWN

BERMUDA

15

ZO'YSIA AND TIFLAWIN

BERMUDA

1

shown by soil test of samples collected in late winter. The unlimed soil apparently did not reach a level sufficiently low to greatly reduce the growth of the grasses. Zoysia and bermuda grew well at pH as low as 4.7.
TABLE 10. THE EFFECT OF LIME APPLICATIONS ON AVERAGE

BERMUDA AND ZOYSIA ON FOUR SOILs 1

SOIL PH UNDER

Average annual pH of soil

Lime applied

Bermudagrass 1961-63 1964-66 pH pH

Av. pH

1961-63 pH

Zoysiagrass 1964-66 pH

Av. pH

Decatur clay as needed 2 ------------5.9 6.4 6.2 none ------------------4.8 4.8 4.8 Hartsells fine sandy loam 2 as needed ? -6.0 6.6 6.3 none -----------------------4.6 4.7 4.7 Norfolk sandy loam as needed2 ------------- 6.5 5.9 6.2 none ------------------------ 4.7 4.7 4.7 Norfolk fine2 sandy loam as needed ------------5.8 6.4 6.1 none ------------------4.7 4.7 4.7

5.7 4.9 6.0
4.7

6.4 4.8 6.5
4.8

6.1 4.9 6.3
4.8

6.0 5.0
5.9

6.4 5.0
6.3

6.2 5.0
6.1

4.7

4.7

4.7

'The rate of P applied was 88 lb. and of K was 166 lb. per acre. 2 To maintain pH at near 6.5.

Effect of Lime on Ca, Mg, P, and K Content Lime (dolomite) application increased the Ca and Mg content of the plants, Table 11. The P content was not affected in bermuda but was increased in zoysia. The K content was lowered by lime in most cases. These data are from treatments that had adequate. amounts of P (88 pounds) and K (166 pounds) annually in the fertilizer, thus, the lowering of the K content was of no significance in affecting the growth of the grasses. Under a low K fertilizer program, the lime might have produced poor growth of the grasses as a result of a reduction of K uptake by the plants. There were no differences in appearance or earliness in bermuda or zoysia attributable to lime treatments. Soil Test Relationships The soils data were not different for zoysia and bermudagrass, and the soil test values reported in Tables 12 and 13 are the averages for both grasses. The soil test values for phosphorus, Table 12, are related to rate of annual application. There was little change in soil

16

ALABAMA

16 TABLE 11.

~~~~ALABAMA AGRICLTRLEPIMNSAIO

AGRICULTURAL

EXPERIMENT

STATION

AVERAGE CA, MG, P, AND K CONTENT OF DRY MATTER AS AFFECTED 1 BY LIME

Lime

Bermudagrass

applied Decatur clay2 as needed

Ca Pct.
-----------

Ca, Mg, P, and K content of dry matter Zoysiagrass P Mg Ca K P Mg Pet. Pct. Pet. Pct. Pct. Pct. 0.18 .14 .18 .14
.19

K Pct. 1.42 1.41 1.37 1.51
1.34

0.48 .42 Hartsells fine sandy boa .50 as needed 2 -------.43 none -------------Norfolk sandy loam as needed 2-------.44 none ------------Norfolk fine 2 sandy boar n .51 as needed --------

none

0.35 .34 .36 .34
.33

1.40 1.54 1.24 1.46
1.27

0.40 .32 .41 .33
.42

0.18 .12 .19 .16
.16

0.35 .31 .34 .30
.36

.54

.13 .19
.13

.33 .33
.31

1.40 1.37
1.51

.34 .38
.31

.12 .19
.11

.32 .35
.29

1.29 1.36
1.46

none_

-___________________

.42

'The rate of P applied was 88 lb. and of K was 166 lb. per acre. 2 To maintain pH at near 6.5.
SOIL TEST VALUES BY YEARS1 ON SOIL TYPES AT 4 RATES OF P APPLIED

TABLE 12.

P applied

1961 p.pm.

1962 ... 0 2 2 0 1 5
6

Soil Test P 1964 1963 pp.m. p... 0 1
1

1966 1965 p.p.m. pp.. 3 2 3 2 2 4
5

OP 1 - -___________ Decatur ci Hartsells fsl____________ 1 3 --------------Norfolk s0 Norfolkfsl-Average -------------------- - 1 22 P Decatur ci_____________ 6 6 - -----Hartsells fsl ---Norfolk si_____________ 12

1 1 3
3

0 2 2

0

1 2
3

1 3 3 2 2

5
5

Norfolkfsl3----3--14----------------

3

11
3

8 4 14 18 26 11 17 61 70 70 76 69

8 3 12 16 29 11 17 73 71 84 72 73

9 5 13 17 34 15 20

10
6

Decatur cl_____________ _ 17 15 Hartsells fsl________________

Average -----------------------44 P

7

6 15 16 32 11 18 59 52 68 56 59

6 17 22 40 20 25

Norfolk sl_____________ 25 _ 11 Norfolk fsl__________ 17 -___ Average __________ 88 P Decatur ci_____________ 54 Hartsells fsl____________ 49 Norfolk si_____________ 61 Norfolk fsl_____________ 48 Average _____________ 53
was added as needed.

93 86 107 102 108 118 102 110 102 104 and bermudagrass plots. Treatments applied at 32' rate in fall 'Average zoysia and 32rate in the spring. The rate of K applied was 166 lb. per acre. Dolomite

ZOYSIA AND TIFLAWN BERMUDA

17

TABLE 13.

SOIL TEST VALUES BY YEARS ON SOIL TYPES AT 4 RATES 1 OF K APPLIED

K applied

1961 p.p.m.

1962 p.p.m. 44 19 20 17 25 53 30 24 32 35 67 47 50 48 53 175 93 63 80 103

Soil Test K 1964 1963 p.p.m. p.p.m. 35 27 16 19 24 46 30 22 24 30 66 50 32 30 44 156 101 60 80 99 37 25 24 24 26 42 31 26 30 32 59 40 46 35 45 151 93 68 79 98

1965 p.p.m. 33 30 24 28 29 44 36 33 36 37 50 37 45 44 44 148 115 97 111 118

1966 p.p.m. 29 17 20 25 23 39 38 31 37 36 54 37 40 36 42 153 109 94 93 112

OK 60 Decatur cl 29 Hartsells fsl Norfolk sl------------24 18 Norfolk fsl 32 Average 42 K 73 Decatur cl 50 Hartsells fsl__ 38 Norfolk sl 35 Norfolk fsl 49 -Average 83 K 116 Decatur cl 57 Hartsells fsl 40 Norfolk sl 48 Norfolk fsl 65 Average 166 K 179 Decatur cl 102 Hartsells fsl 55 Norfolk sl 66 Norfolk fsl 100 Average

1Average zoysia and bermudagrass plots. Treatments applied at 3, rate in fall and , rate in the spring. The rate of P applied was 88 lb. per acre. Dolomite was added as needed.

test P values over the 6-year period for the 0, 22-, and 44-pound rates. This indicates that approximate equilibrium conditions had been established between amount applied and removed for each rate by the third year of application, 1961. At the 88-pound rate of application, there was a gradual increase of P on all soils. The soil test values for potassium showed some change over the years and also by soil type, Table 13. On Decatur, the K values decreased at all rates of application. The other soils showed no change or a slight decrease for the 0-, 42-, and 83-pound rates, but an increase for the 166-pound rate. These data show that 44 pounds of P (100 pounds P 205) and more than 83 pounds of K (100 pounds K20) were required to maintain the 1961 levels of P and K in these soils. The highest rate of P, 88 pounds per acre (200 pounds P 205), increased soil test values in all soils. The highest rate of K, 166 pounds per acre (200 pounds K20), increased soil test values on the two Norfolk soils. The soil tests of Hartsells

18

ALABAMA

AGRICULTURAL

EXPERIMENT

STATION

and Decatur did not change appreciably at this rate of application. It should be emphasized that in this study the N rate used was 400 pounds per acre with all clippings removed. Had the N rate been lower and clippings not removed, more buildup is likely to have occurred. Rouse (11) reported, based on cotton and corn calibration research, that it was necessary to classify soils into at least three different classes to permit pooling data for soil test calibration. The data from this study do not show that this would be necessary for soils on which lawn grasses are grown. This could have been the result of a high rate of P and K removal in the clippings from these high-yielding plots. The relationship between soil test P and K and the relative yield for all treatments and both grasses are plotted in Figures 1 and 2. It should be pointed out that yields from treatments receiving 22, 44, and 88 pounds of P were influenced by application of the element as well as soil test values. Because an approximate equilibrium condition was established and maintained by the semiannual application of the variable element, Tables 12 and 13, it is considered that any bias would be reflected in slightly higher yield for a given soil test value than would have occurred if the application had not been made. A curve describing the relationship between soil test value and

FIGURE 1. Relationship between soil test P in the top 2 inches of soil and relative yields of zoysia and Tiflawn bermudagrasses grown on 4 soil types.

ZOYSIA

AND

TIFLAWN

BERMUDA

19

I00

/
So
6 -0

Q

0

Bermudo y/ o
or Q

(Zero Applied) 42/b K Applied
83

Oy

0or
" or -

ib K Applied
lb K Applied

166

Zoysioand

TiflownBermudogross

40

Coastal Bermudogross

20

0

20

40

60

80

100

120

140

160

180

Soil Test K (ppm)

FIGURE 2. Relationship between soil test K in the top 2 inches of soil and relative yields
of zoysia and Tiflawn bermudagrasses grown on 4 soil types.

relative yield reported for Coastal bermudagrass by Rouse (11) is also plotted on these graphs. Considering the direction of any bias resulting from an application of the element, it would appear that the relationship determined for Coastal bermudagrass grown for hay on Coastal Plains soils at 200 pounds of N would be valid for these two grasses managed for lawn at 400 pounds of N. The results show a critical level for soil test value of P of about 15 p.p.m. At this figure and above, there was little response to P applications. At a level of 7 p.p.m. and below, there was a definite deficiency. This is in agreement with the findings of Bingham (1) and Lunt (7). The critical level of soil test value of K was about 50 p.p.m. Above this figure, there was little response. At 30 p.p.m. or below, there was a definite deficiency. SUMMARY AND CONCLUSIONS A study to determine the effect of different rates of phosphorus and potassium and the addition of lime on yield, mineral content, and appearance of zoysia matrella and Tiflawn bermuda showed that soil test values could be used as a guide for the application of phosphorus, potassium, and lime.

20 20

ALABAMA

AGRICULTURAL

EXPERIMENT

STATION

ALABAMA AGRICULUA

XEIMN

TTO

Results indicate that fertilizer recommendations given for many turf areas specify larger amounts than are required for good growth and appearance and that soil testing would serve as a valuable guide to the application of phosphorus or potassium more in keeping with the needs of the plant. Soil test values showed a critical level of 15 p.p.m. for P and 50 p.p.m. for K. Above these values, there was little response to applications of these elements in a fertilizer. At a value of 7 p.p.m. or below for P and of 30 p.p.m. or below for K, there was a definite deficiency. The results indicated that at 400 pounds of N annually with the clippings removed, the application of 44 pounds P (100 pounds P20 5) per acre with 83 pounds K (100 pounds K20) would be adequate on most soils of Alabama with an initial soil test of low or medium. Analysis of plants indicates that a P content of 0.3 per cent and a K content of above 1.0 per cent are adequate for plant growth. The critical level of P was 0.2 per cent and K was 1.0 per cent. Over fertilization with P may produce adverse effects on appearance of zoysia. This occurred at the 88-pound P (200 pounds P2 05) application rate when the soil test P level was 75 p.p.m. No evidence of injury from too much K was noticed.

ZOYSIA

AND

TIFLAWN

BERMUDA

21

LITERATURE CITED (1) Bingham, F. T. 1962. Chemical Soil Tests for Available Soil P. Soil Sci. 94: 87-95. (2) Evans, E. M., R. D. Rouse, and R. T. Gudauskas. 1964. Low Soil Potassium Sets Up Coastal for Leafspot Disease. Highlights of Agr. Res. 11: No. 2. Auburn Univ. (Ala.) Agr. Exp. Sta. (3) Ferguson, Marvin H. 1964. Fertilizer-How Much? USGA Green Sect. Rec. II: No. 4. (4) Goss, Roy L. and C. J. Gould. 1968. Turf Diseases: The Relationship to Potassium. USGA Green Sect. Rec. V: No. 5. (5) Juska, F. V. and A. A. Hanson. 1967. Phosphorus and Its Relationship to Turfgrass and Poa annua. California Turfgrass Culture. 17: No. 4. (6) Juska, F. V., A. A. Hanson, and C. J. Erickson. 1964. Response of Kentucky Bluegrass and Red Fescue to Several Levels of P. USGA Green Sect. Rec. I: No. 5. (7) Lunt, O. R., R. L. Bronson, and S. B. Clark. 1967. Response of Five Grass Species to Phosphorus on Six Soils. California Turfgrass Culture. 17: No. 4. (8) Morgan, Wayne L. 1968. The Effects of Nutrients on the Grass Plant. The Golf Superintendent. 36: No. 4. (9) Oertli, J. J. 1963. Nutrient Disorders in Turfgrass. California Turfgrass Culture. 13: No. 3. (10) Page, N. R. et al. 1965. Procedures Used by State Soil Testing Laboratories in the Southern Region of the United States. So. Coop. Series Bul. 102. (11) Rouse, R. D. 1968. Soil Test Theory and Calibration for Cotton, Corn, Soybeans, and Coastal Bermudagrass. Auburn Univ. (Ala.) Agr. Exp. Sta. Bul. 375.

AGRICULTURAL EXPERIMENT

STATION SYSTEM
UNIVERSITY

OF ALABAMA'S LAND-GRANT

IO
With an agricultural research

o
Q 1 12* 0 0

unit in every major soil area, Auburn University serv es the needs of field crop, livestock, forestry, and horticultural producers in each region in Alabama. Every citizen of the State has a stake in this research program, since any advantage from new and more economical ways of producing and handling farm products directly henefits the consuming public.

0

©

0

Research Unit Identification *Main
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22.

Agricultural Experiment Station, Auburn.

Tennessee Valley Substation, Belle Mina. Sand Mountain Substation, Crossville. North Alabama Horticulture Substation, Cullman. Upper Coastal Plain Substation, Winfield. Alexandria Experiment Field, Alexandria. Forestry Unit, Fayette County. Thorsby Foundation Seed Stocks Farm, Thorsby. Chilton Area Horticulture Substation, Clanton. Forestry Unit, Coosa County. Piedmont Substation, Camp Hill. Plant Breeding Unit, Tallassee. Forestry Unit, Autouga County. Prattville Experiment Field, Prattville. Black Belt Substation, Marion Junction. Tuskegee Experiment Field, Tuskegee. Lower Coastal Plain Substation, Camden. Forestry Unit, Barbour County. Monroeville Experiment Field, Monroeville. Wiregrass Substation, Headland. Brewton Experiment Field, Brewton. Ornamental Horticulture Field Station, Spring Hill. Gulf Coast Substation, Foirhope.