PLACE IN RETURN BOX to remove this checkout from your record.
TO AVOID FINES return on or before date due.
MAY BE RECALLED with earlier due date if requested.

 

DATE DUE DATE DUE DATE DUE

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

5/08 KzlProj/AccsxPraleIRCIDaIeDue.indd

FIELD STUDIES ON THE SELECTIVE CHEMICAL CONTROL
OF TWO BENTGRASS SPECIES IN BLUEGRASS

AND IN RED FESCUE TURF

by

Warren Rasmus Bredahl

A THESIS

Submitted to the College of Science and Arts of
Michigan State University of Agriculture and Applied Science
in partial fulfillment of the requirements

for the degree of

MASTER OF SCIENCE

Department of Botany and Plant Pathology

1961

ABSTRACT

FIELD STUDIES ON THE SELECTIVE CHEMICAL CONTROL
OF TWO BENTGRASS SPECIES IN BLUEGRASS
AND IN RED FESCUE TURF

by Warren Rasmus Bredahl

Field studies were conducted over a two-year period in an
attempt to discover a chemical which would be effective as a selective
herbicide for bentgrass which has become established in bluegrass
or red fescue turf.

Turf research plots of three common lawn grass species,
Kentucky bluegrass (Poa pratensis), Merion bluegrass (a selection
from g, pratensis>, and Creeping red fescue (Festuca rubra), were
seeded. The area was divided into two equal parts then one half

was cross-seeded with Colonial bentgrass (Agrostis tennis) and the

 

other half cross-seeded with Creeping bentgrass (Agrostis palustris).
Since all seeding was done at one time, the various grass species
had attained comparable growth and development when the herbicidal
treatments were applied. One granular and seven liquid formulations
of chemicals were applied at various rates. Plots were rated on

the basis of comparative phytotoxicity of the herbicides to all

grass species present. Special emphasis was placed on the recording
of discoloration and survival of both the desirable grass species

and the bentgrass species.

ii

iii

Bentgrasses and red fescue were about equally susceptible
to injury by the chemicals except when 2, 4, S-TP was applied
at 2 lbs. per acre. Another treatment, a mixture of dalapon and
silvex caused extreme top burning of all grasses, but all species
except red fescue, later recovered and restored the stand. Both
bentgrass species almost completely replaced the red fescue the
following season.

The bentgrasses exhibited varying degrees of susceptibility
to injury by the chemicals, but in no instance was either of the
bentgrass species completely eliminated.

2, 4, S-TP gave the most effective control of bentgrass

without injury to bluegrass.

I.
II.
III.

IV.

V.

VII.

TABLE OF CONTENTS

INTRODUCTION ...................................
LITERATURE REVIEW .............................
MATERIALS AND EXPERIMENTAL METHODS ............
M$MHS..u.u.u.u.n.u.u.u.u.u.n.u.
Observations One Month After Treatment .......
Observations Nine Months After Treatment .....
Observations Fifteen.Months After Treatment ..
DISCUSSION ...................................

SUMY 00.00.00.000...OOOOOOOOOOOOOOOOOOOOOOO

BIBLIOGRAPI‘IY OOOOOOOOOOOOOOOOOIOOOOOOOOOOOOOOO.

iv

1

5

7

ll

12

l6

16

21

24

26

A o
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A 5
A O

TABLE 1

TABLE 2

TABLE 3

TABLE 4

TABLE 5

LIST OF TABLES

Herbicides, Formulations and Rates per

Acre Applied for the Control of Bentgrasses.
(All Rates are Expressed in Pounds per ‘

Acre 0f ACtiVe Ingredient.) 00000000000000.0000.

Ratings of Grass Species, Based on Visual
Observations, 33 Days After Application
Of HerbiCidESooooooooooooooooooooooooooooooooooo

Ratings of Grass Species, Based on Visual
Observations, 70 Days After Application
Of HerbiCid-esooocooooooooooooooooooooooooooooooo

Percent of Bentgrasses and of Bare Soil
in Turf Treated with Herbicides 15 Months
After TreamentOOOOO.OOOOOOOOOOOOOOOOOOOOOO.O...

Relative Distribution of Each Grass

Species 15 Months After Application

of Herbicides. No. of Inches in Which

EaCh SPBCLeS occurredoooooooooocoooooooooooooooo

l3

INTRODUCTION

The presence of bentgrass in lawns composed of bluegrass,
fescue, or mixtures of bluegrass and fescue is a serious weed
problem. (See Plate 1.) Eighty percent of all grass seed mixtures
on the market today have a small percentage of bentgrass seed in
them. One viable bentgrass seed per pound of grass seed mixture
is sufficient to infest a lawn.

Bentgrass can be used to produce a beautiful, fine textured,
and attractively colored turf which is satisfactory for lawn
purposes. Such turf, however, requires an intensive care and
‘management schedule and is highly susceptible to the growth of
fungi which cause the turf diseases known as brownpatch, dollar
spot, melting-out and snow mold. Bentgrass turf also requires
frequent mowing at a short height as well as periodic mechanical
perforation of the dense mat which interferes with proper aeration
and with penetration of water into the sod. Because of these
requirements, as well as the marked textural differences between
bentgrass and other commonly used turf grasses, it is not a suitable
component of a turf grass mixture (2).

In recent years herbicides have been used extensively for
the selective control of weeds in turf. Technological progress
in finding selective herbicides to control bentgrass has been
slow. Comparatively little research has been done and few data
have been published with respect to controlling bentgrass in
other turf grasses. Therefore, a study of certain chemical formu-
lations that might selectively eliminate bentgrass in bluegrass

or red fescue turf seemed timely.

1!

There is no selective chemical generally used for bentgrass
control. Therefore, when a bluegrass lawn becomes 50% or more
infested with bentgrass there are three courses of action:

1. Switch to bentgrass culture.

2. Chemically eliminate all grass and re-seed.

3. Small isolated patches of bentgrass may be physically

removed and the area reseeded or resodded.

This research presented here was undertaken to determine
the influence of a few specific chemical formulations, separately
and in combination, and at various rates of application per acre,

on the grass species involved.

 

 

 

 

 

Plate 1. Patches of bentgrass in lawn turf. Note color,

texture, and density of the bentgrass.

 

 

 

Plate 2. A general view of a section of the experimental
plots. The numbered plots were treated as follows:

Plot 10 - 2, 4, 5 TP at 2 1bs./A

Plot 11 - 2, 4-D at 2 lbs./A

Plot 8 - 2, 4-D at 2.7 1bs./A

Plot 4 - dalapon-+ silvex at 9.5 + 2.5 1bs./A

BLOCKS OROSS-SEEDED WITH SEASIOE

BLOCKS CROSS-SEEDED WITH HIGHLAND

BENTGR ASS

BENTGRASS

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

A.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

FIGURE

 

 

 

I l

KENTUCKY BLUEGRASS

 

 

 

 

H—PLor———-I-

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

"’ MERION BLUEGRASS § 36
fl.
/ I
X
0
§
5 RED FESCUE
D
m l g
LU
\4 u 5...!2 ,7 5,14qu

 

 

 

 

 

DETAILED BLOCK DIAGRAM

EXPERIMENTAL TURF PLOT LAYOUT

LITERATURE REVIEW

Creeping and colonial bentgrasses produce a shorter, thicker,
and finer textured turf than bluegrass or red fescue (2). Creeping
bentgrass sends out profuse, creeping stems that produce new plants
at every node which results in the formation of a dense sod.
Colonial bentgrass is a tufted-type grass with few creeping stems
or stolons. It forms a dense turf when heavily seeded and closely
mowed (3).

The speed with which bentgrasses invade bluegrass and red
fescue lawns has been clearly shown by Davis (1) at the Ohio
Agricultural Experiment Station, where bentgrass completely dominated
all mixtures in which bentgrass seed was present. Merion bluegrass
and red fescues were more resistant to invasion than common.Kentucky
bluegrass. Invasion occurred less rapidly at mowing heights of
2 inches than at 3/4 inch. The dense sod formed by Merion bluegrass
made it more resistant to bentgrass invasion than is the sod of
common.Kentucky bluegrass.

Kreitlow and Juska (5) reported in 1960 that when a bluegrass
lawn, infested with,bentgrass, is mowed 1% - 2 inches in height,
dry or dead spots result from accumulation of bentgrass runners
because water cannot permeate the mat and continue into the soil.
This condition, known as thatch, is sometimes mistaken for a disease.

Shaw, et a1. (7) reported in 1960 that among the factors known

to influence foliar distribution, retention, and uptake of herbicides

by grass plants are leaf form and shape, orientation, density,
surface, and margins. The erect growth habit of bluegrass and
red fescue contrasts markedly with the spreading or prostrate
habit of most bentgrass species. Colonial bentgrass is slender
and somewhat erect in growth habit and has very narrow leaves.
The slender culms of Creeping bentgrass originate from a decumbent
base. The leaves are short, flat, firm, and taper-pointed.

Plants with upright and those with horizontal leaf orientation
form foliage canopies of various densities and differ markedly
in their retention and absorption of herbicides.

Daniel (8) 1961, reported the use of UF-85 (26 percent urea
and 59 percent formaldehyde) at 2 gallons per 1000 square feet
in an attempt to control bentgrass in bluegrass turf. The turf
was mowed short, sprayed with the herbicide to completely wet
the foliage and then covered with a plastic sheet. He reported
complete control of bentgrass in six different tests, but in every

test only a few bluegrass rhizomes survived.

MATERIALS AND EXPERIMENTAL METHODS

A. Establishment of experimental turf plots:

As a prerequisite to proceeding with this problem, experimental
turf plots of a specific composition were prepared. These plots
were established on a fairly well-drained, level, sandy loam soil
on the experimental farm of Michigan State University, East Lansing,
Michigan, in September 1959. The usual soil fitting procedures
of disking,rdragging with a springtooth harrow and finishing with
a spiketooth harrow just prior to seeding, were followed. The
plot area had been plowed early in the summer and periodically
tilled until the time of final fitting.

The area was hand raked with a garden rake to remove humps
and fill depressions. Stones, clumps of sod, and other debris
were removed prior to fertilizing and seeding. A 12-6-6 analysis
commercial fertilizer was applied uniformly at a rate of 20 lbs.
per 1000 sq. ft. Fertilizer application was followed by a light
raking.

The plot layout, Figure 1, consisted of six rectangular
blocks 30 x 36 feet with a six-foot aisle separating the blocks.
Each of the blocks was divided into three 12 x 30 feet rectangular
sub-blocks.

Creeping Red Fescue, Merion Bluegrass, and Kentucky Bluegrass
were sown at the rate of 1 lb. per 1000 sq. ft. in strips 12 feet

wide across each of the blocks. One half of the area, was cross-

8

seeded with Highland bentgrass and the other half seeded with
Seaside bentgrass, both at the rate of 0.8 ounce per 1000 square
feet. This quantity represents 5% of the amount of the selected
turf grass seed used.

All seeding was done on September 17, 1959. The sub-blocks
were lightly raked on the short axis immediately following seeding.
The aisles were neither seeded nor chemically treated. All plots
were thoroughly sprinkled after seeding. Six days following
seeding heavy rainfall caused portions of three blocks to be
under flood water for up to three days. Some minor erosion occurred
across the short axis of all blocks. No seedlings had emerged
at the time of flooding, but apparently a high percentage had
germinated and become anchored as there was no evidence of species
having been carried across sub-block borders. By the end of
the 1959 growing season the turf appeared normal except for a
few sparse areas where flooding had been greatest.

The spring of 1960 was cool and wet, therefore conditions
were ideal for the growth of fall seeded turf. The sparse areas
filled in rapidly, and by April satisfactory lawn turf had develOped
in each block.

The usual turf cultural practices used in maintaining a bluegrass
or red fescue lawn were followed. No additional fertilizer was
applied during the experiment. A11 blocks were kept mowed at
1% - 2 inches height throughout the experiment. Grass clippings

were removed from the turf at the first mowing. A rotary type

power mower was used exclusively. The plots were irrigated when
necessary. Broad-leaved weeds did not become established in any
of the plots during the course of the experiment.

Some of the chemicals were selected for the experiment on
the basis of research results reported in technical bulletins
and proceedings of turfgrass and weed control conferences. Others
were chosen because of the warning on the containers that the
particular herbicide might damage bentgrass. Some were included
upon the suggestion of field representatives of certain chemical
companies.

A total of eleven chemical treatments was applied, with
two replications, in each of the two bentgrass sections. Plots
for liquid treatments were 4 feet wide, whereas the plots for
dry formulations were 3 feet wide. The dry, granular, chemical
formulation was applied with an 18-inch mechanical spreader.

The liquid formulations were applied with a 2 gallon pressure
sprayer using water as a carrier. There were two plots on which

no chemicals were applied in each bentgrass section. The chemicals,
formulations, and rates used are shown in Table 1.

All chemical applications were made on July 29, 1960. The
soil surface and turf were dry, the temperature was 82 degrees

F., and the humidity was low.

Table 10

for the control of Bentgrasses.

10

pounds per acre of active ingredient.)

2.

4.

5.

10.

11.

12.

Herbicide

Zytron

Zytron

Zytron

Dalapon-

silveX‘mix-

ture

TD 47

TD 62

Endothal

2,4-1)

ester

2,4,5-T

2,4,5-TP

2,4-D

None

Chemical Analysis Form

 

O-(2-4 dichlorophenyl)
o~methyl isoprOpyl phos-
phoramidothioate. Granular
O-(2-4 dichlorophenyl)
o-methyl isoprOpyl phos-
phoramidothioate. Granular
O-(2-4 dichlorOphenyl)
o~methyl isopropyl phos-
phoramidothioate. Granular
2, 2-dichloropropionic

acid, sodium salt, + 2-
(2,4,5-trichlor0phenoxy)

propionic acid, propylene

glycol butyl ether esters. Liquid

Derivative of disodium 3,
6-endoxohexahydr0phtha-
late. Liquid
Derivative of disodium 3,
6-endoxohexahydrophtha-
late. Liquid
Disodium 3, 6-endoxohexa-
hydrophthalate Liquid
2,4-dichlorophenoxyacetic
acid, butoxy ethanol
ester. Liquid
2,4,5-trichlor0phenoxy-

acetic acid, propylene

glycol butyl ether esters. Liquid

2-(2,4,5-trichlorophenoxy)
propionic acid, propylene
glycol butyl ether esters. Liquid

2,4-dichlor0phenoxyacetic
acid, butoxy ethanol ester. Liquid

Herbicides, formulations and rates per acre applied

(All rates are expressed in

Pounds
per Acre

10

15

20

905-205

2.7

RESULTS

Seven days after the application of the herbicides discoloration
of grass foliage was observed in all plots which had received chemical
applications. The combination of dalapon and silvex caused a
severe browning and apparent tOp-kill of all grasses. Endothal
and its derivatives likewise caused a browning effect upon all
species but to a lesser extent than that of the dalapon and silvex
mixture.

The growth regulating herbicides, 2, 4-D, 2, 4, 5-T and
2, 4, S-TP caused a certain amount of discoloration of all grasses
but the effects were more pronounced on some species than on
others. The highest dosage level of 2, 4-D, 2.7 lbs. per acre,
caused a severe injury to red fescue and to both species of bentgrass.
At the 2.0 lb. level, however, all species showed only minor
injury by the herbicide. The response to 2, 4, S-T indicated
that red fescue and bentgrass were less tolerant of this herbicide
than was bluegrass. The greatest amount of selective action was
observed in the plots treated with 2, 4, S-TP. In these plots,
fescue and bentgrasses were severely burned whereas the bluegrasses
showed only mild discoloration.

The application of zytron did not cause any marked, immediate
injury but appeared to have stimulated growth of all species.

This effect was shown by the production of a deep green color in

the foliage and a somewhat greater height of the grass leaves.

11

12

Observations One Month After Treatment

Ratings of apparent toxicity of the herbicide, based on
visual observations, were made 33 days after application of the
herbicides and are presented in Table 2. Injury to each grass
species was given a numerical value on a scale of 0 to 10 where
a value of 0 indicates no apparent injury and a value of 10 represents
a complete kill of top growth.

At the time of these observations, variations in the response
of all the grass species were noticeable. Generally, red fescue
and both bentgrasses showed more injury than did either type
of bluegrass.

Severe effects of the dalapon-silvex mixture were noted
7 days after treatment. The top growth of all species was killed
in plots treated with the dalapon-silvex mixture (Plot 4 of Plate
2).

In all plots where 2, 4, 5-TP was applied (Plot 10, Plate 2)
complete destruction of top growth of bentgrasses and red fescue
occurred. The two types of bluegrass, however, showed very little
injury. .

Plots 8 and 11(Plate 2), treated with 2, 4-D at dosage levels
of 2.0 and 2.7 pounds per acre, respectively, gave evidence of
the narrow limit of tolerance for this herbicide by fescue and
bentgrass. These grasses were injured only to a slight extent
at the 2 pound level but 55 percent of the stand was destroyed
at the 2.7 pound level. Bluegrass was not effected seriously

at either dosage level.

l3

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14

The effects Produced by 2, 4, S-T were similar in all respects
to those produced by equivalent amounts of 2, 4-D.

Zytron, at the 10 pound dosage rate, had not produced any toxic
effects after 33 days. Rates of 15 and 20 pounds of this compound,
however, had caused some retardation of the growth of all grass
species. All of the zytron plots were dark green in color and
no selective tolerance between species could be observed.

All grasses treated with endothal and the derivative TD 62
had recovered after 33 days, from the injury observed 7 days after
treatment. However, the endothal derivative TD 47 appeared to
have a more persistent toxicity and caused some stunting of the
turf grasses.

All plots were examined and rated again on October 1, 1960,
seventy days after the initial herbicidal applications. The ratings,
in Table 3, are not essentially different from those made 33
days after treatment. They did indicate, however, that Seaside
bentgrass has less ability to recover from the herbicide used
in these trials than does Highland bentgrass.

Plots treated with zytron, endothal, and the two endothal
derivatives appeared to have made complete recovery and no reduction
in stand of any grass species was observed.

Red fescue was almost completely destroyed in plots treated
with 2, 4-D; 2, 4, S-T and 2, 4, S-TP. Some bentgrass was present
in all these plots and the amount of Highland bentgrass was greater
than that of Seaside bentgrass. Both types of bluegrass appeared

to have made complete recovery from any injury.

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16

Observations Nine Months After Treatment

 

Examination of the plots in June 1961 led to the conclusion
that the grass species were approaching stabilization and that
reasonable estimates of the ultimate effects of the herbicial
applications could be made. Quantitative data were obtained
by random selection of three areas each one square foot in extent,
and estimating the relative portions of these areas occupied
by bentgrass. The extent of bare soil was estimated in the same
manner. These data, for all treatments, are presented in Table
4.

The data show that none of the herbicides killed all the
bentgrasses and that all except 2, 4, S-TP, have seriously affected
the ability of red fescue to retard the rate of invasion by bentgrasses.
The data also indicate that Seaside bentgrass spreads at a more
rapid rate than does Highland bentgrass. There are no important
differences between the rate of invasion in Merion and Kentucky
bluegrasses.

Endothal, 2, 4-D and 2, 4, S-TP caused significant reduction
in the growth of Seaside bentgrass but had lesser effects upon
Highland bentgrass.

The relatively small amounts of bare soil found was considered
as an indication that, except in the red fescue plots, the herbicides
had not reduced the stand of turf grass to any considerably extent.

Observations Fifteen Months After Treatment
In November 1961, fifteen months after the herbicides were

applied, final evaluation of the effects of herbicidal treatments

 

 

 

 

 

 

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.s «Heme

18
on all grass species was made. For this purpose a line transect,
100 inches in length was made diagonally across each of the plots,
and the number of inches in which each species occurred was determined.
Frequency of occurrence of a species in the inch units is a measure
of the distribution of the various species and variations in
distribution are attributed to the effects of the various herbicidal
applications upon growth of the five kinds of grasses. The relative
frequencies of all species are shown in Table 5.

At the time of final evaluation, there were no plots in which
bentgrass had been eliminated and no evidence of residual toxicity
from herbicides could be observed. Effects of herbicides on the
stand of turf grasses were visible but recovery of the bluegrasses
was completed.

Differences in growth habit of the two types of bentgrass
were shown by the more frequent appearance of Seaside bentgrass
in all plots where this grass was seeded than that of Highland
bentgrass in the portion seeded to the latter type.

Plots in which severe injury had followed application of
the herbicides generally were heavily infested with bentgrass.

Other grass species had made reasonable recovery and had formed
satisfactory turf.

Best control of bentgrasses was obtained in the plots treated
with 2, 4, 5-TP, and 2, 4, S-T. Neither of these compounds caused
permanent reduction in the stand of bluegrass but did reduce the

apparent stand of red fescue in half of the plots.

19

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20

Seaside bentgrass had made full recovery in plots treated
with zytron, dalapon-silvex, endothal, and the derivatives of
endothal. Highland bentgrass had not made complete recovery in
either of the bluegrass species.

The results observed in the 2, 4-D plots were variable and

not consistent with the dosage applied.

DISCUSSION

The chemical treatments were applied in this experiment before
the bentgrass had established definite clumps or patches. The
bentgrass plants were, therefore, partially protected from sprays
by the leaves of other species.

Results obtained in this experiment indicated that if a herbicide
did not kill bentgrass but depressed the vigor of desirable turf
grasses, then, as a result of reduced competition, bentgrass
quickly occupied the area. Bluegrass appeared to possess much
greater capacity to resist bentgrass invasion and greater herbicide
tolerance range than did red fescue.

None of the herbicides permanently reduced the stand of the
bluegrass species. Red fescue and the bentgrasses were about
equally susceptible to the herbicides used, but there was a wide
difference in stand restoration capacity. The bentgrasses were
markedly more aggressive in restoring the stand and subsequently
spreading than was fescue.

The fact was noted that the bare ground, which occurred in
the red fescue plots as a result of the action of herbicides,
was quickly occupied by bentgrass plants. A notable exception
occurred in the 2, 4, S-TP plots. The bare areas in these plots
remained mostly devoid of any growth until the second season.
Growth of scattered red fescue and bentgrass clumps tended to fill

the bare spots and form a solid cover of vegetation.

21

22

2, 4, S-TP was the most effective herbicide in controlling
bentgrass. Although growth of red fescue was seriously reduced,
bentgrass growth was likewise reduced, and in this instance the
bentgrass did not progress toward domination as it did in all of
the other treatments to which bentgrass was susceptible.

The results obtained in this study show clearly that there
are wide variations in the responses of turf grass species to
herbicides. The data also point to the great capacity of grasses
to recover from injury to top growth as well as to the lack of
systemic effects of growth regulating compounds on grasses.

Red fescue, in these trials, was more susceptible to chemical
injury than was any of the other grasses. Kentucky and Merion
bluegrasses were not injured by most of the herbicides and also
showed considerable ability to compete successfully with bentgrass.

While none of the herbicides eliminated bentgrass, some of
them produced sufficient effect to suggest a possible way to
bring bentgrass under control. The limited injury to bluegrass
by 2, 4, S-TP, suggests that this herbicide might be utilized
in a program of repeated applications, during two growing seasons,
and perhaps lead to complete destruction of bentgrass in the
treated area.

The data presented in this report are not sufficient to permit
one to propose a method for general use but they do indicate a
need for additional research along the lines followed in this
study. Combinations of herbicides, repeated applications, alternate

applications of two or more herbicides, etc., appear to be types

23

of investigations which could lead to the development of a control

program for bentgrass in turf.

SUMMARY

Turf plots of Kentucky bluegrass, Merion bluegrass and red
fescue were overseeded with either Seaside or Highland bentgrass
in order to provide a bentgrass infestation somewhat similar to
that which often develops in lawn turf.

Eight herbicides, selected for their known effects upon grasses,
were applied in an attempt to control bentgrass selectively in
the other turf grasses.

All grass species were injured by the herbicides, but the
two bluegrass types made rapid recovery and no permanent injury
was observed.

Red fescue was injured more severely than any of the other
species. This effect was shown by actual killing of fescue plants
and by the failure of plants which survived to form a turf in
the plots.

Both types of bentgrass were severely injured by all herbicides
except zytron. None of the herbicides killed all the bentgrass.

Seaside bentgrass was injured more severely, recovered more
quickly, and spread more profusely in the other grasses than did
Highland bentgrass. The recovery and pr0pagation capabilities
of Seaside bentgrass are due to its characteristic production of
creeping stems that develop roots and stems at every node, whereas
Highland bentgrass is a tufted-type grass with few creeping stems

and rhizomes.

24

25

The herbicide 2, 4, S-TP was the most effective material
for the control of bentgrass and did not cause permanent damage
to bluegrass.

Ester formulations of 2, 4-D and 2, 4, S-T caused temporary
suppression of bentgrass but the effects were scarcely visible
at the end of the second growing season.

The possibility of developing a control program for bentgrass,
based on repeated applications of 2, 4, S-TP is suggested.

Results obtained in this study emphasize the need for additional
research in this field and suggestions for certain lines of approach

are made.

BIBLIOGRAPHY

Davis, R. R. 1958. The Effect of Other Species and Mowing
Height 23 Persistence 2: Lawn Grasses._ Agronomy Journal

Vol. 50:671-673, 1958.

Tyson, James and Grigsby, Buford. 1952. Growing Beautiful
Lgflgg. Extension Bulletin 224 Michigan State College COOperative
Extension Service.

Harper, John C. II and M. A. Hein. 1957. Better Lawns.

U.S. Department of Agriculture Home and Garden Bulletin No. 51.
Davis, Richard R., James L. Caldwell and George R. Gist.

‘22 g ngg. 1960. The Ohio State University and the U.S.
Department of Agriculture, c00perating.

Kreitlow, K. W. and F. V. Juska. 1960. Lawn Diseases.

Home and Garden Bulletin No. 61, U. S. Department of Agriculture.
Quid; £9_Better Lawns and Gardens. 1956. American Chemical
Paint Co.

Shaw, W. C., J. L. Hilton, D. E. Moreland, and L. L. Jansen.
1960. Herbicides 12 Plants. Craps Research Division, Agriculture
Research Service, U. S. Department of Agriculture

Daniel, W. H. 1961. Department of Agronomy, Purdue University.

Private communication, 1961.

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