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1985 Insect Pest Management Guide
FIELD and FORAGE CROPS

You must be certified as a pesticide applicator to use restricted-use pesticides.
See your county Extension adviser in agriculture for information.

FEDERAL AND STATE LAWS

The U.S. Environmental Protection Agency is clas-
sifying pesticides for "general" or "restricted" use. Only
a few pesticides have been classified (Table 1).

Commercial applicators who apply restricted-use pes-
ticides must be certified. Commercial applicators include
persons applying a pesticide for hire and governmental
personnel, chemical company representatives, and others
involved in demonstrational, regulatory, and public health
pest control. Certification as a commercial applicator
requires passing a written examination administered
either by the Illinois Department of Agriculture or the
Department of Public Health.

Private applicators who use restricted-use pesticides
"for the purpose of producing any agricultural com-
modity on property owned or rented by him or as
exchange labor (no compensation) on the property of
another" must also be certified, either by attending an
educational training program or by passing an exami-
nation.

Educational training programs for farmers (private
applicators) and commercial pesticide applicators are
conducted by the Cooperative Extension Service to
prepare persons for certification. For additional infor-
mation, consult your county Extension adviser in agri-
culture. The actual certification and the issuing of
permits or licenses are handled by the Illinois Depart-
ment of Agriculture or the Illinois Department of Public
Health.

Insecticides and Classifications

At the time this publication was in preparation, only
a few of the insecticides listed below had been classified
for either "restricted" or "general" use by the EPA.
Additional insecticides are expected to be classified
before the 1985 planting season. Some soil insecticides
(Counter, Dyfonate, Furadan, Mocap, and Thimet) are
expected to be classified before 1986.

The chemical names used in this circular may be
unfamiliar to you. These names are the common, coined
chemical names and as such are not capitalized (for
example, terbufos). Trade names are capitalized (for

example, Counter). In the table of limitations (Table
15), the trade names are listed first, with the common
name in parentheses following the trade name. In the
tables of suggestions, only the trade name is listed.

Table 1. Insecticide Classifications

a

Common name Trade name Classification

acephate Orthene unclassified

Bacillus thuringiensis Dipel, Thuricide, unclassified

Bactur, SOK

carbaryl Sevin unclassified

carbofuran * Furadan restricted3

carbophenothion Trithion unclassified

chlorpyrifos Lorsban unclassified

diazinon Diazinon unclassified

dimethoate Cygon unclassified

disulfoton *Di-Syston restricted*

ethion Ethion unclassified

ethoprop * Mocap restricted'

fenvalerate *Pydrin restricted6

fonofos * Dyfonate restricted'

malathion Cythion, malathion unclassified

methidathion *Supracide restricted6

methomyl Tannate, *Nudrin restricted0

methoxychlor methoxychlor unclassified

methyl parathion *Methyl parathion restricted6

methyl parathion *Penncap-M restricted6

(microencapsulated)

permethrin *Ambush, *Pounce restricted6

phorate Thimet unclassified

phosmet Imidan unclassified

terbufos Counter unclassified

trichlorfon Dylox unclassified

trimethacarb Broot unclassified

a Liquid formulations are restricted.
b All formulations are restricted.

c All formulations except water-soluble packages, 25% wettable pow-
der, and granulars are restricted.

Asterisks (*) are used throughout this circular to
indicate insecticides classified for "restricted" use.

UNIVERSITY OF ILLINOIS AT URBANA-CHAMPAIGN COLLEGE OF AGRICULTURE COOPERATIVE EXTENSION SERVICE
In cooperation with ILLINOIS NATURAL HISTORY SURVEY CIRCULAR 899 (revised annually) November, 1984

Special Local Need Registrations

Section 24(c) of the amendments to the Federal
Insecticide, Fungicide, and Rodenticide Act of 1972
allows states the right to register pesticides for use within
the state to meet special local needs (SLN). The authority
for state registration of pesticides is the Illinois Depart-
ment of Agriculture. A special label, which lists the new
24(c) uses, is printed by the formulator. A copy of this
label must be in the possession of the operator during
application of the pesticides.

POLICY STATEMENT

The Illinois Insect Pest Management Guide: Field and
Forage Crops (Circular 899) is revised annually and is
intended for use during the current calendar year only.
Not all insecticides registered for crop pests are included
in this circular. Insecticides that are effective and do not
present an undue hazard to the user are suggested
whenever possible.

Trade names have been used for simplicity, but their
usage does not imply the endorsement of one product
over another, nor is discrimination intended against any
product.

This guide for insect control is based on research
results from the Illinois Natural History Survey, the
University of Illinois Agricultural Experiment Station,
other experiment stations, and the U.S. Department of
Agriculture.

Be sure to check with your county Extension adviser
in agriculture if you are in doubt about an insecticide
you plan to use. We will make announcements of new
labels and changes in recommendations through the
news media to keep you up to date.

REFERENCES

Fact sheets (designated by NHE numbers) discussing
nonchemical control methods, descriptions of specific
insects, and their life history and biology can be obtained
from the office of the county Extension adviser in
agriculture or by writing to Entomology Extension, 172
Natural Resources Building, 607 East Peabody Drive,
Champaign, IL 61820.

PEST-MANAGEMENT SCOUTING PROGRAMS

Integrated Pest Management (IPM) and pest scouting
have become increasingly important. IPM is a systematic
method of looking for pests in the field, of determining
whether any control measures are needed, and if there
is a problem, of deciding on the proper measures to
use. Pest scouting enables farmers to detect and control
pest outbreaks before significant yield losses occur. Be-
cause decisions on chemical control are based on eco-
nomic thresholds and not on guesswork, IPM programs
also keep unnecessary pesticide use to a minimum.

Pest scouting has been accepted as an important

management tool by many Illinois farmers in the past
several years. As farming costs increase, growers are
realizing the advantages of treating a field only when
an economically harmful pest population occurs, rather
than treating it automatically regardless of the situation.
By using pesticides on this basis, farmers have a better
chance of reducing management costs.

Pest scouting programs have been initiated by several
pest-management consulting firms throughout the state.
In addition to pest scouting, most offer other services
such as soil testing and nematode monitoring.

PESTICIDE SAFETY

Certain precautionary steps should be taken when
handling insecticides. The insecticides suggested in this
publication can be poisonous to the applicator. The
farmer or applicator is expected to protect himself, his
workers, and his family from needless exposure.

When using insecticides, apply all the scientific knowl-
edge available to make sure that there will be no illegal
residue on the marketed crop. Such knowledge is con-
densed on the label. READ THE LABEL CAREFULLY
AND FOLLOW THE INSTRUCTIONS. The label
should be recent and not from a container several years
old. Do not exceed the maximum rates suggested. Ob-
serve the interval between application and harvest. Apply
only to crops for which use has been approved. Keep
records of pesticide use for each field. Record the
product used, the trade name, the percentage content
of the insecticide, the dilution, the rate of application
per acre, and the date or dates of application.

Always handle insecticides with respect. The person
most likely to suffer ill effects from insecticides is the
applicator. Accidents and careless, needless overexpo-
sure can be avoided. Following these rules will prevent
most insecticide accidents:

1. Wear rubber gloves when handling insecticide
concentrates.

2. Do not smoke, eat, or drink while handling or
using insecticides.

3. Keep your face turned to one side when opening,
pouring from, or emptying insecticide containers.

4. Leave unused insecticides in their original con-
tainers with the labels on them.

5. Store insecticides out of the reach of children,
irresponsible persons, and animals; store preferably in a
locked building. Do not store near livestock feeds. Better
yet, buy no more pesticide than you will use, thus elimi-
nating a pesticide storage and disposal problem.

6. Triple rinse, bury, or burn all empty insecticide
containers or take them to an appropriate sanitary
landfill.

7. Do not put the water-supply hose directly into
the spray tank or blow out clogged nozzles or spray
lines with your mouth.

8. Wash with soap and water exposed parts of the
body and clothes contaminated with insecticides.

9. Do not apply to fish-bearing or other waters.

10. Do not leave puddles of spray on impervious
surfaces or apply insecticides near dug wells or cisterns.

1 1 . Do not apply insecticides, except in an emer-
gency, to areas with abundant wildlife.

12. Do not spray or dust when weather favors drift.

13. To avoid bee kill, apply insecticides after bee
activity has been completed for the day; use the least
toxic materials. Warn beekeepers that you are applying
insecticides.

Refer to the Illinois Pesticide Applicator Study Guide
for more information concerning safe handling of pes-
ticides and treatment of pesticide poisoning.

POTENTIAL FOR SOIL INSECT PESTS IN CORN

There are many factors that affect soil insect popu-
lations and their potential to damage corn. The type of
crop rotation greatly influences whether a soil insect
problem will occur and what kind it will be. Weather,
weeds, soil type, planting date, hybrid, tillage, and
natural enemies also influence insect populations. Knowl-
edge about soil insect damage in a particular field during
previous years is also helpful because infestations tend
to occur in the same fields and in the same area.

Illinois Extension entomologists have estimated the
probability of the occurrence of soil insect pests in corn
on the basis of cropping sequence (Table 2). These
estimates can serve as a guide to determine the risk of
damage caused by soil insects and the need for applying
a soil insecticide at planting.

Corn After Soybeans. The potential for soil insect
problems in corn after soybeans is generally low, and
the use of soil insecticides rarely pays. Corn rootworms
rarely cause damage to corn after soybeans. In most

fields, a diazinon + lindane planter-box seed treatment
will be adequate to protect against attack by seedcorn
beetles, seedcorn maggots, and wireworms. Scout the
field for cutworm damage as the plants emerge from
the soil.

White grubs are an occasional problem in east-central
Illinois in corn after soybeans.

Corn After Corn. The potential for rootworm damage
is moderate to severe wherever corn follows corn in
Illinois. A rootworm soil insecticide may be needed in
most fields of corn after corn. Wireworms are occasion-
ally a problem in the southern part of Illinois. Scout for
cutworm damage.

Corn After Grass Sod. Wireworms and white grubs
are potential problems. Apply a labeled soil insecticide
at planting time. Scout for cutworm damage.

Corn After Sorghum. A planter-box seed treatment
of diazinon or diazinon + lindane will protect the corn
seeds against seedcorn maggots. Scout the fields for
cutworms as the corn emerges. Corn rootworms are
rarely a problem where corn follows sorghum.

Corn After Legumes. Cutworms, grape colaspis, grubs,
and wireworms occasionally damage corn planted after
clover and alfalfa. In addition, adult northern corn
rootworms are sometimes attracted to legumes or to
blooming weeds in legumes for egg laying, particularly
in years when beetles are forced to leave adjacent fields
of drouth-stressed corn to seek food. A soil insecticide
should be considered for this cropping sequence.

Corn After Small Grain. There is a slight potential
for damage by wireworms, seedcorn beetles, and seed-
corn maggots in corn after small grain, particularly
wheat. In most instances, a diazinon + lindane planter-
box seed treatment will be adequate. If wireworms are

Table 2. Probability Estimates of Economic Soil Insect Damage in Corn and Suggestions for Control According to Cropping
Sequence, Illinois

Crop

preceding

corn

Insect pest

Need for

a soil
insecticide

Wireworm

Cutworm

Corn
rootworm

White
grub

Seedcorn
maggot

Billbug

Grape
colaspis

Recommended pest
management practices

Soybeans

1:500

1:25

1:10,000

1:1,000

1:150

1:100

1:1,000

very low

Use planter-box seed treatment;
scout for cutworms.

Corn

1:200

1:100

2:3

1:1,000

1:50

1:100

1:5,000

mod-high

Scout for rootworm beetles; treat
corn if population exceeds 1 per
plant at any time during August.

Small grain

1:100

1:50

1:100

1:250

1:50

1:200

1:5,000

low

Bait for wireworms prior to plant-
ing.

Legume

1:25

1:25

1:50

1:150

1:10

1:50

1:4

low-mod

Bait for wireworms prior to plant-
ing.

Grass sod

1:10

1:25

1:500

1:10

1:25

1:50

1:1,000

mod-high

Use soil insecticide for wireworms
and white grubs; if no-till, scout for
foliar insect damage as corn emerges.

present, use a soil insecticide at planting time. Excessive
weed cover in small grain stubble fields may have been
attractive to northern corn rootworm beetles for egg
laying as the beetles moved from adjacent fields of
drouth-stressed corn.

CORN ROOTWORM SITUATION

Problem Area

Populations of northern and western corn rootworm
beetles were extremely high in 1984. Although the
potential for rootworm damage to corn following corn
is greatest in the northern two-thirds of the state,
moderate to severe damage to corn roots by larvae may
occur in any field where corn follows corn in Illinois.

Rootworm Soil Insecticide Failures, 1984

Corn rootworm larval control with soil insecticides
was very erratic in Illinois during 1984, in both farmers'
fields and research trials. Instances of poor control were
observed with all rootworm soil insecticides, carbamates
and organophosphates, over a wide geographical area
with various soil types and weather conditions. An
investigation of some of the problem fields has disclosed
several factors that probably contributed to poor control
with the insecticides. The factors that stand out but are
not easily quantifiable include too much rain immedi-
ately following planting, dry soil conditions during June,
a late rootworm egg hatch, above-average rootworm
larval populations, and improper calibration of insecti-
cide applications (rates that were too low).

In some fields, heavy rains immediately following
planting hastened the decomposition of soil insecticides
and reduced control. In others, lack of rain prevented
the movement of the insecticide from the soil surface
or off the granular carrier to the area where rootworm
larvae were feeding. Early planting also may have been
a contributing factor in some fields because soil insec-
ticides applied in April or early May could have lost
much of their potency by the time eggs hatched in mid-
June. Hence late hatching larvae escaped the insecticide,
resulting in extensive root damage and ultimately a large
number of beetles. Undoubtedly, several of these con-
ditions in combination could have affected the perfor-
mance of soil insecticides.

Unfortunately the factors that influence the perfor-
mance of soil insecticides under field conditions are not
well understood. Recent research indicates that the
breakdown of some soil insecticides by soil microorgan-
isms is accelerated after repeated applications of the
same compound. The soil microorganisms use the in-
secticide as an energy source, so their populations in-
crease to a level where they are able to break down the
insecticide very rapidly. As a result, the insecticide has
a progressively shorter residual time in the soil. This

seems to be most prevalent in fields where the same soil
insecticide has been used for several consecutive years;
however, the pattern is neither clearcut nor predictable.
In all probability, environmental conditions combined
with accelerated degradation of the insecticides by mi-
croorganisms are major causes for insecticide failures.

Are the rootworms more tolerant to the soil insec-
ticides? Although this has not been confirmed, some
research data suggest that some slight change in suscep-
tibility has occurred with some compounds. Unfortu-
nately most tests to detect resistance are conducted with
the adult stage rather than the damaging larval stage.
So at this point, tolerance to insecticides cannot be ruled
out.

Determining Potential for Damage in 1985

Corn growers should base the need for using a
rootworm soil insecticide in 1985 on the abundance of
rootworm beetles in cornfields during late summer of
1984. If beetle numbers reached or exceeded one per
plant at any time during late July, August, or September,
1984, plan to apply a rootworm soil insecticide if the
field is to be replanted to corn in 1985.

Fields of corn planted in late May or June, 1984,
may have extensive rootworm damage if replanted to
corn in 1985. During August and September, rootworm
beetles are especially attracted to late planted or late
maturing fields. Seeking fresh pollen and silks to feed
on, the beetles lay millions of eggs in these fields.
Planting the fields to a crop other than corn in 1985 is
suggested to reduce the rootworm population.

SUGGESTIONS FOR ROOTWORM CONTROL, 1985

In recent years, the performance of rootworm soil
insecticides has been quite variable. They have per-
formed effectively at some locations and have been
marginal or ineffective at others. This trend could
continue in 1985. An immediate solution to the phe-
nomenon of erratic rootworm soil insecticide perfor-
mance is not readily available. Perhaps there is none. It
is entirely possible that changes brought about by treat-
ing millions of acres of corn with soil insecticides over
the past 20 years have introduced an era when rootworm
control with current soil insecticides will be highly
variable.

Looking to 1985, you should seriously consider crop
rotation, particularly in fields where there is a high
probability of rootworm damage. Other alternatives
include applications of a soil insecticide at planting or
at cultivation. Considering the erratic performance of
planting-time treatments in 1984, a cultivator applica-
tion in early June near the beginning of rootworm egg
hatch should be an effective option. However, for most
farmers planting time treatments of a soil insecticide

will be the predominant method of rootworm control.
If you use a soil insecticide at planting, plan to check
fields in early to mid June to determine whether damage
is occurring. If so, a cultivator application may be
needed.

Crop Rotation

Crop rotation is an extremely effective way to prevent
damage by northern and western corn rootworm larvae.
If feasible, do not grow corn two years in succession in
the same field. First-year corn following soybeans will
generally not require a soil insecticide for rootworm
control.

Although rootworm beetles can be found in "clean"
or weed-free soybean fields, and may even lay a few
eggs there, the number of eggs is not great enough to
warrant the use of a soil insecticide on corn the following
season. In a few instances, rootworm larval damage has
occurred to corn planted after soybeans when the bean
field had been heavily infested with volunteer corn or
weeds during August. Adult northern and western corn
rootworms were attracted to these weedy soybean fields
to deposit eggs. As a result, root damage by larvae
occurred the following season. Good weed control in
soybeans will prevent rootworm damage in corn follow-
ing soybeans. Soybean fields with 5,000 or more vol-
unteer corn plants per acre will usually warrant treat-
ment for rootworm control the following year if planted
to corn.

Corn rootworm beetles deposit the vast majority of
their eggs in cornfields. The larvae cannot survive on
the roots of broadleaf crops (soybeans or alfalfa) or
broadleaf weeds. Consequently, when a crop other than
corn, soybeans for example, is planted in a field with
soil containing millions of rootworm eggs, the rootworm
larvae die before becoming egg-laying beetles.

Soil Insecticides

The suggestions for rootworm control that follow
are based on research conducted by entomologists in
Illinois and other states.

At Planting. Apply Broot 15GX, Counter 15G, Dy-
fonate 20G or 4EC, Furadan 15G or 4F, Lorsban 15G,
Mocap 15G, or Thimet 20G in a 7-inch band at the
suggested rate (see Table 3). IMPORTANT: Read the
suggestions in the section on alternating rootworm soil
insecticides.

Soil insecticides will give 50 to 70 percent control
of corn rootworm larvae. This degree of control is
adequate to prevent economic levels of larval damage
in most fields. But in some heavily infested fields enough
larvae may survive to cause economic levels of root
damage, and beetle populations may be large enough
to interfere with pollination.

Planting-time treatments applied in early April may
provide only marginal control. Consider a cultivator
application in late May or early June in such fields,
rather than a treatment at planting time.

Liquid formulations. Dyfonate 4E or Furadan 4F may
be mixed with water and applied as a spray in a 7-inch
band ahead of the press wheel. They may also be mixed
with liquid fertilizer and used with a split-boot applicator
at planting.

Incompatibility or crop injury may be a problem in
treatments using a liquid insecticide with a liquid fertil-
izer at planting. The insecticide must be compatible with
the fertilizer. Conduct a test before planting to make
certain that the two are physically compatible. Maintain
agitation in the tank after mixing and during application
to prevent separation. Use caution when handling
liquid insecticide formulations.

At Cultivation. Apply Counter 15G, Dyfonate 20G,
Furadan 15G or 4F, Lorsban 15G or 4E, Mocap 15G,

Table 3. Soil Insecticides Suggested for Rootworm Control, Illinois, 1985

Time of
application

Ounces of

product per

1 ,000 ft. of row

Amount of product

needed per acre

Insecticide*

40" rows

38" rows

36" rows

30" rows

Broot 15GX

At planting

8

6.7 lb.

7.0 lb.

7.4 lb.

8.7 lb.

Counter 15G

At planting or cultivation

8

6.7 lb.

7.0 lb.

7.4 lb.

8.7 lb.

Dyfonate 20G

At planting or cultivation

6

5.0 lb.

5.3 lb.

5.6 lb.

6.7 lb.

♦Dyfonate 4E
♦Dyfonate 4E
Furadan 15G

At planting

Preplant

At planting or cultivation

2.4 fl. oz.
Broadcast

8

2 pints

3 quarts
6.7 lb.

2'/s pints
3 quarts
7.0 lb.

2XA pints
3 quarts
7.4 lb.

2'/4 pints
3 quarts
8.7 lb.

♦Furadan 4F
Lorsban 15G

At planting or cultivation
At planting or cultivation

2.4 fl. oz.

8

2 pints
6.7 lb.

2'/s pints
7.0 lb.

2'/4 pints
7.4 lb.

2V* pints
8.7 lb.

Lorsban 4E
Mocap 15G

At cultivation

At planting or cultivation

2.4 fl. oz.

8

2 pints
6.7 lb.

2'/s pints
7.0 lb.

2'/4 pints
7.4 lb.

2'/4 pints
8.7 lb.

Thimet 20G

At planting or cultivation

6

5.0 lb.

5.3 lb.

5.6 lb.

6.7 lb.

'Consult text for more information. LIQUID FORMULATIONS ARE HIGHLY TOXIC.
* Use restricted to certified applicators only.

or Thimet 20G on both sides of the row at the base of
the plants just ahead of the cultivator shovels. Cover
the insecticides with soil. The best time to apply a basal
treatment of a soil insecticide by cultivator is in late
May or early June, near the beginning of egg hatch.

A cultivation-time application of a soil insecticide is
an alternative to a planting-time application or may be
used as a "rescue" treatment if the planting-time insec-
ticide fails to control rootworm larvae. In either case,
you should dig up several plants and examine the roots
and surrounding soil for rootworm larvae. If you find
3 or more larvae per plant, a cultivator application is
warranted.

Soil moisture may affect both application and effec-
tiveness of cultivation-time treatments. Fields that are
too wet may never be cultivated. On the other hand,
the insecticide may not perform satisfactorily if the soil
is too dry.

Suggestions For Alternating Rootworm Soil Insecti-
cides. Laboratory and field research indicates that using
the same rootworm soil insecticide for several consec-
utive years can eventually lead to erratic, if not poor,
rootworm control. This first became apparent in Illinois
during the mid-1960s when northern and western corn
rootworms developed resistance to aldrin and hepta-
chlor, about 5 years after these compounds were first
used in the field.

Buxten, a carbamate soil insecticide introduced in
1967, gave good rootworm control until the early 1970s,
but was dropped from University of Illinois's recom-
mendations in 1974 after problems with control had
developed. Furadan, also a carbamate soil insecticide,
was used by many farmers with excellent results from
1969 until 1975 when control became erratic. More
recently, Amaze, an organophosphate that had provided
excellent rootworm control in research trials, was re-
moved from the soil insecticide market by the manu-
facturer following poor rootworm control in 1983 —
only 3 years after being registered.

A lesson to be learned from the preceding scenario
is that extensive and continuous use of any one com-
pound may contribute to erratic results and to its
eventual failure.

A review of the factors that might have contributed
to erratic rootworm control in 1984 suggests that late
egg hatch, dry soil during June and July, and intense
population pressure were the causes. However, if there
are other underlying factors, the scenario observed in
1984 may be repeated in 1985, but on a larger scale.

Illinois entomologists encourage growers to consider switch-
ing rootworm soil insecticides occasionally, rather than using
one product for several consecutive years.

Consider the following suggestions for alternating
rootworm soil insecticides:

1 . If performance of a soil insecticide has been poor
in a particular field in recent years, do not use the same
insecticide in that field in 1985.

2. The continuous use of one insecticide may lead
to a buildup of soil microorganisms that hasten the
breakdown of an insecticide or to insect resistance. To
avoid this possibility, consider switching rootworm in-
secticides occasionally rather than using one compound
year after year.

3. Consider alternating organophosphate and car-
bamate soil insecticides. Keep in mind, however, that
growers generally have had no advance warning of poor
control where problems have occurred.

4. If a carbamate (Furadan, Broot) was used in 1984,
switch to an organophosphate (Counter, Dyfonate, Lors-
ban, Mocap, Thimet) in 1985. Avoid using carbamates
in consecutive years or in fields where performance has
been unsatisfactory in past years.

5. In fields with a history of organophosphate use,
the carbamates should perform satisfactorily. If the
organophosphate gave poor or erratic rootworm control
in 1984, consider switching to a carbamate.

Summary: Planning Your Rootworm Control Program

1. Alternate corn with another crop when possible,
particularly in fields where rootworm beetles averaged
1 or more per plant last summer, or if the soil insecticide
did not give effective rootworm control in 1984.

2. If you intend to grow corn after corn and root-
worm beetles averaged 1 or more per plant last summer,
apply a rootworm soil insecticide at planting time. Apply
the rate suggested in Table 3 and consider our sugges-
tions for alternating rootworm soil insecticides.

3. Consider a cultivation-time application of a root-
worm soil insecticide if you intend to plant in early April
or if your planting-time insecticide does not provide
effective control.

4. Scout for rootworm beetles in July and August,
1985, to determine the potential for rootworm larval
damage in 1986.

Scouting to Determine Rootworm Potential in 1986

The abundance of rootworm beetles in a cornfield
in July and August is an excellent indicator of future
rootworm problems. Corn growers can determine the
potential for rootworm damage in 1986 by counting
western and northern corn rootworm beetles from mid-
July through August, 1985, in this way:

1 . Make 3 or more counts for western and northern
corn rootworm beetles at 7- to 1 0-day intervals between
mid-July and late August in fields to be replanted to
corn.

2. Examine 5 plants selected at random in each of
10 areas of the field. Count all of the western and

6

northern corn rootworm beetles on 50 plants each time.
The counts take about 45 minutes in a 40-acre field.

3. As you approach a plant, move quietly to avoid
disturbing the beetles. Count the beetles on the entire
plant, including the ear tip, tassel, leaf surface, and
behind the leaf axils.

4. Record the number of beetles you find per plant.
If the average is more than one beetle per plant for any
sampling date, plan to apply a rootworm soil insecticide
in 1985. If average populations range from Vt to 1
beetle per plant, the probability of economic damage
the following year is low, and a soil insecticide is likely
to be unnecessary. If populations do not exceed an
average of lA beetle per plant for any sampling date, a
soil insecticide will not be needed the following season.

Rootworm Life Cycle

Western and northern corn rootworm beetles deposit
their eggs in the soil at the base of the corn plants or
between rows during August and September. The eggs
overwinter in the soil and begin hatching in late May.
Egg hatch usually takes place over a period of 3 to 5
weeks. Consequently, in July and August all stages of
the corn rootworm — egg, larva, pupa, and adult —
may be found. The rootworm larvae feed on the roots
of corn plants during June, July, and August. When a
larva is fully grown (V2 inch), it builds a cavity in the
soil and goes into the pupal or resting stage. After 5 to
10 days, the beetle emerges from the soil. The devel-
opment from egg hatch to adult emergence takes 27 to
40 days. After the females emerge from the soil and
mate, 14 days or more elapse before they begin laying
eggs. Rootworm beetles may deposit as many as 1 ,000
eggs; an average of 500 per female is probably common.
Most egg laying in Illinois occurs after August 1 .

CORN CUTWORMS

The occurrence and extent of cutworm infestations
are difficult to predict each year. Sandhill, dingy, and
claybacked cutworms all overwinter in Illinois as partially
grown larvae, but their populations are seldom wide-
spread. As a result, they cause damage early in the
growing season in scattered areas. Sandhill cutworms
are a problem in sandy areas almost every year. Dingy
and claybacked cutworms occur more frequently in corn
planted after sod or forage legumes than in other crop
rotations.

Black cutworms do not overwinter in Illinois, so out-
breaks are difficult to forecast. Infestations of black
cutworm larvae arise from eggs laid by moths that fly
into Illinois in the early spring. A statewide program of
monitoring black cutworm pheromone traps provides
information about the time and intensity of spring moth
flights.

Certain factors favor black cutworm outbreaks. The
most important factors may be late planting and preplant

weed infestations. Fields that are tilled and planted late
are more likely to develop a preplant weed infestation
than fields that are planted early. These late-planted
fields with weeds are more attractive to cutworm moths
as a site on which to deposit their eggs.

Currently, two options are available for cutworm
control: preplant or planting-time applications of soil
insecticides to prevent damage and rescue treatments
after the infestation appears.

Because of the uncertainty in predicting which fields
will have light, moderate, or heavy infestations of cut-
worms, it may be more feasible to use rescue treatments
for cutworm outbreaks rather than to use a preplant or
planting-time treatment unnecessarily.

Based on the relatively low incidence of cutworm
problems over the past 25 years, a grower may find an
economic advantage to the wait-and-see system, which
involves field scouting rather than a costly always-apply
program in which the soil insecticide is routinely applied
at or before planting for a problem that may not exist.

Rescue (or emergency) treatments to control outbreaks
of cutworms include sprays of Ambush, Lorsban, Pounce,
or Pydrin, or Sevin pelletized bait. Broadcast the pel-
letized bait on the surface, but do not incorporate.
Ambush, Lorsban, Pounce, and Pydrin sprays should
also be broadcast.

The keys to effective cutworm control with the rescue
treatments are the amount of surface moisture and the
movement of the worms. Control may be poor, regard-
less of the insecticide used, if the topsoil is dry and
crusted and the worms are working below the soil
surface. When the soil is dry, the high rate of Ambush,
Lorsban, Pounce, or Pydrin is recommended.

To determine the need for rescue treatments, scout
the fields during plant emergence, particularly those
fields considered to be high-risk. Early detection of leaf-
feeding or of cutting by cutworms is vital. When the
corn plants are beginning to emerge, check the fields
for leaf-feeding, cutting, wilting, or missing plants. Small
cutworm larvae (less than V2 inch) feed on the leaves
and do not begin cutting plants until they are about
half grown.

A control measure is needed on corn in the 2-leaf
stage if 3 percent or more of the plants are cut and if
there are 2 or more cutworms per 100 plants. At the
4-leaf stage, control is justified if 3 percent or more of
the plants are cut and if there are 4 or more worms
per 100 plants. A single cutworm will cut fewer of the
4-leaf plants than those in the 2-leaf stage.

Planting-time treatments are relatively effective in con-
trolling light to moderate infestations, but control may be
unsatisfactory for heavy infestations. Lorsban 1 5G, Mocap
1 5G, Dyfonate 20G, Counter 1 5G, and Furadan 1 5G are
registered for the control of cutworms in corn. Lorsban
has provided the best cutworm control in research trials.

The Mocap label states that Mocap will "control light to
moderate infestations of black and sandhill cutworms";
Dyfonate is labeled for "light and moderate infestations of
black cutworms"; Counter and Furadan are labeled for
"suppression of cutworms." Some growers may want to
use one of these products in fields with a history of cutworm
problems or in high-risk fields.

Preplant broadcast treatments of Lorsban 4E and Dy-
fonate 4E are also registered for corn cutworm control.
Lorsban is labeled at rates of 1 to 2 quarts per acre;
the higher rate is suggested. Dyfonate is labeled for
"suppression of black cutworms" at 4 quarts per acre.
Both insecticides should be incorporated into the top 2
to 4 inches of soil immediately after application.

Replanting may be required if cutworm damage is
extremely severe. Before replanting apply Lorsban 4E
as a broadcast spray at 3 to 4 pints per acre, and
incorporate the insecticide into the top 2 to 4 inches of
soil. Or you can apply a labeled granular insecticide. If
the cutworm infestation is heavy, the Lorsban spray will
be more effective.

WIREWORMS

Wireworms may attack the seed or drill into the base
of the stem below ground level, damaging or killing the
growing point. Damage will show up as wilted, dead, or
weakened plants and spotty stands. Wireworm larvae
are yellowish-brown and wirelike; several species are
known to attack corn. They live for two to five years
in a field in the larval stage, feeding on the roots of
grasses and crops. Their presence is often related to the
crops or weeds that were in the field two to four years
before damage to the corn. Most reports of damage to
corn have been in fields where corn follows soybeans
or where there has been a corn-soybean-small grain
rotation. The adult (a click beetle) prefers to deposit its
eggs in small-grain stubble or in grassy fields.

Attempts to control wireworms with an insecticide
rescue treatment after the damage appears are not very
successful. Therefore, if an infestation is known to be
present, an insecticide should be applied at planting.

Wireworms are usually most damaging in bottom-
lands or in poorly drained areas on upland soils. Low
spots in the field often have the heaviest populations.

The proportion of fields of corn affected by wire-
worms in Illinois is small (less than 1 percent) and does
not justify the widespread use of a soil insecticide on
first-year corn after soybeans. A diazinon + lindane
planter-box seed treatment may help deter the wire-
worms from attacking the seed but will not protect the
seedling.

Checking for Wireworms

A technique using baits has been developed for
evaluating wireworm potential before planting. The bait

stations should be established 2 to 3 weeks before the
anticipated planting date. Fields where small grain or
grasses have been grown the preceding 2 or 3 years are
the best candidates for bait stations.

Since wireworm infestations are usually not uniform
within a field, it will be necessary to place the bait
stations randomly throughout the field. One bait station
per acre is desirable. As a minimum, place 2 stations at
the highest elevation in a field, 2 on a slope, and 2 in
the lowest area.

Follow this procedure for baiting:

1 . Use a mixture of 1 cup of untreated wheat and
1 cup of untreated shelled corn at each station.

2. Bury the bait about 4 inches deep. It is also
desirable to cover the ground over each bait station
with an 18-inch square of black plastic. The plastic
collects solar heat and speeds germination of the corn
and wheat, which entices overwintering wireworms.

3. Mark each station with a flag or stake.

4. Dig up the bait stations in 10 to 14 days and
count the number of wireworms.

Need for Treatment

If you find an average of one wireworm per bait
station, use a labeled soil insecticide. In some instances,
several wireworms may be found in one bait station and
none in others. Wireworm infestations tend to concen-
trate in some locations. It may be possible to limit
treatment to areas where the concentration is heaviest.

WHITE GRUBS

Several species of economically important white grubs
have 3-year life cycles. Peak years of damage usually
occur during the year following large flights of May
beetles, the adult stage of white grubs. The beetles
prefer to lay their eggs in ground covered with vege-
tation, such as weedy soybean fields and sod.

The C-shaped white grub larvae chew on the roots
and root hairs of corn seedlings. During peak years of
damage, the grubs feed all season long. Damage to a
cornfield is most apparent in the spring. Symptoms of
white grub injury visible aboveground are irregular
emergence, reduced stands, and stunted or wilted plants.
The damage is usually spotty throughout the field.

There are no effective rescue treatments for white
grubs after the damage appears. However, if plants show
symptoms of injury, dig around the root system of several
corn plants. If white grubs are causing the problem and
replanting is warranted, use a labeled soil insecticide.

PLANTER-BOX SEED TREATMENTS

Corn. Use a seed treatment in fields that do not
receive a soil insecticide at planting time. A planter-box
seed treatment with diazinon will protect germinating
corn against attack by seedcorn beetles and maggots. A
diazinon + lindane planter-box seed treatment protects

8

seed from attack by seedcorn maggots, seedcorn beetles,
and wireworms. Lorsban 50-SL is labeled as a slurry
treatment on seed before planting to protect germinat-
ing seed against injury by seedcorn maggots and beetles.
NOTE: Excess dust from the seed treater may interfere
with the electronic monitor in air planters.

Soybeans. Use a diazinon or diazinon + lindane seed
protectant to prevent damage to germinating soybeans
from seedcorn maggots. Follow the label directions for
application. The potential for damage is greatest during
cool, wet springs when germination is slow.

CALIBRATION FOR GRANULAR SOIL INSECTICIDES

Calibrate the applicators for granular soil insecticides
before the planting season begins. In some instances,
poor control is caused by applying rates that are too
low. Proper calibration will help avoid this problem.
Most soil insecticide bags have a list of suggested settings
for the particular model of applicator. The settings are
based on planting speed. The beginning settings are help-
ful, but be sure to check your actual application rate
under your own operating conditions.

Follow these steps for calibrating the applicator:

1. Calibration of granular applicators for soil in-
secticides is usually based on ounces of product needed
per 1,000 feet of row. Consult the insecticide label or
Table 3 for labeled rates for rootworm control. These
rates are expressed in ounces per 1,000 feet of row and
in pounds of product per acre.

2. Consult the label or manufacturer's recommen-
dation for an approximate application setting. Adjust
the setting on each hopper.

3. Select an area for a test run, preferably in the
field so that speed and traction conditions are constant.
Measure off 1,000 feet.

4. Fill the hoppers and attach a plastic bag or
container to each delivery tube to catch the granules
from each hopper.

5. Drive the premeasured distance (1,000 feet) at
the same speed to be used during the planting operation.

6. Weigh the material collected from each hopper.
Use a scale that weighs in ounces (e.g., a postal scale or
a diet scale).

7. Compare the quantity (ounces) per bag against
those given in Table 3. To obtain one pound of active
ingredient per acre the following amounts of material
should be collected:

Formulation,
percent

Oz. collected
per 1,000 ft.

10
15
20

12
8
6

8. Recalibrate if the difference in quantity applied

during the calibration process is more than 10 percent
over or under the rate suggested on the label.

EUROPEAN CORN BORERS

Corn borer moths begin to emerge in late May in
southern Illinois and mid- to late June in the central
and northern regions. The females lay most of their
eggs in the evening. They spend the daylight hours in
fencerows and other protected areas.

First-generation borers reduce yields by stalk-tunneling,
which weakens the plant and destroys the tissue used to
transport food within the plant.

Corn that is planted early (the fields with the tallest
corn) should be monitored closely from mid-June to
early July for signs of whorl-feeding by corn borer
larvae. The fields with the tallest corn in mid-June are
the most attractive to moths laying eggs for the first
generation. Control is warranted if 50 percent or more
of the plants have fresh whorl-feeding and live borers
are present. Seed production fields should be treated
when 15 to 25 percent of the plants have whorl-feeding
and larvae are present.

Corn hybrids have varying degrees of tolerance or
resistance to leaf-feeding by first-generation borers. Con-
sider this trait when selecting varieties for 1985.

Corn planted late is most attractive to moths laying
eggs for the second generation. Yield losses caused by
second-generation borers are a result of stalk breakage
and ear drop, as well as physiological damage. Corn-
borer entrance holes also provide avenues for stalk rot
organisms. Monitor fields from mid-July to mid-August
for egg masses or newly hatched larvae of the second
brood.

To assess the potential for second-generation corn
borers, start checking for egg masses when moth flight
is under way. Examine a minimum of 25 plants, selected
at random throughout the entire field, and count the
number of egg masses that are found on each plant.
Although the moths usually lay their eggs on the two
or three leaves above or below the developing ear, you
should check all the leaves. One technique is to remove
the leaves one by one, starting at the bottom of the
plant, and carefully scan them for egg masses.

The eggs, which are deposited in masses of 15 to
30, overlap like the scales of a fish. Calm nights favor
egg deposition by the moths. The absence of hard,
beating rains during moth emergence also increases the
potential for infestations.

Egg masses are flat and about half the size of your
little fingernail. Newly deposited eggs are white, then
turn pale yellow, and become darker just before hatch-
ing. Eggs that are about to hatch have distinct black
centers. These are the black heads of the larvae that
are visible through the translucent eggshell. The eggs
hatch in 3 to 7 days, depending on the temperature.
The female moth hides in grass and weeds during the

9

day. Noncrop areas that border cornfields may harbor
large numbers of corn borer moths during the day.
Check these areas for moths as you enter the field to
determine the potential for corn borer infestation.

Treatment is warranted when you find 1 egg mass
for every two plants. Because peak egg laying generally
occurs over a period of 2 to 4 weeks, it will be necessary
to resample fields if egg masses are not present on half
of the plants during the initial survey. If cumulative
counts (taken 1 week apart) exceed 1 egg mass for every
two plants, apply a treatment.

For best results, treatment should be applied soon
after egg hatch to kill the young larvae before they bore
into the plant. The larvae begin tunneling into the stalks
about 10 days after hatching. Because egg laying for
the second generation extends over a 3- to 4-week
period, timing of insecticide application should be pre-
cise. Occasionally, two treatments may be necessary for
satisfactory control.

CORN LEAF APHIDS

Corn leaf aphids are small, soft-bodied, greenish-
blue plant lice about the size of a pinhead. They do not
overwinter in Illinois. Winged corn leaf aphids, blown
into Illinois on southwesterly winds during mid- to late
June, become established within the whorl leaves of the
corn plant. These aphids give birth to living young. In
the absence of predators, parasites, diseases, and hard
beating rains, aphid populations may increase very rap-
idly.

Corn leaf aphids cause damage by sucking moisture
and nutrients from the corn plant. Soil moisture stress
and heavy infestations on the upper leaves and tassel
may result in barren plants or reduced ear size. The
critical period for damage is during tassel emergence
through pollination. If aphids are allowed to cover the
tassel and upper two or three leaves, yield losses are
likely to occur.

Fields should be scouted for aphids, beginning about
one week before tassel emergence. Pull and unroll the
whorl leaves of plants selected at random to check for
aphids. Treatment is suggested if 50 percent of the
plants have 100 or more corn leaf aphids per plant
during tassel emergence and if plants are under drouth
stress. Aphid populations usually decline after pollination
is complete. However, treatment may be warranted
following pollination if aphid populations continue to
cover the tassel and one or two of the upper leaves.

REDUCED TILLAGE AND NO-TILL INSECT PESTS

Concern about insect problems should not keep
growers from adopting conservation tillage practices.
The soil-insect complex in corn, which is similar in many
ways in conventional and reduced-tillage systems, can
be readily controlled by applying soil insecticides at

planting time. Outbreaks of insects feeding on foliage
can usually be controlled with properly timed insecticide
treatments. Close monitoring of fields to detect insect
outbreaks is essential, regardless of the tillage system.

Weather conditions and the type of crop rotations
determine to a great extent whether a soil insect problem
will occur and what kind it will be. In some instances,
tillage may also influence the kind and abundance of
an insect pest. Some tillage operations favor specific
pests. Others tend to reduce pest problems. The general
expectation is that insect infestations will be more pro-
nounced where no-tillage is used in corn than where
conventional or reduced-tillage systems are used.

No-Till Pests

Insect problems occur more frequently in no-till corn
than in any other conservation tillage system and are
often more serious. Crop residue left by the use of no-
till practices provides a stable environment for pest
survival and development. Pests occurring under these
conditions include European corn borer, cutworms, army-
worm, common stalk borer, wireworms, seedcorn maggots,
billbugs, slugs, and mice. Soil insecticides may be needed
on no-till corn following corn (in rootworm area), grass
sod, legumes, or following any crop in which grasses
and broadleaf weeds are prevalent.

Soil Insect Control

Select a soil insecticide that will control the antici-
pated soil insect pest. Consult Table 5 for suggestions.
If a soil insecticide is not applied at planting, a diazinon
planter-box seed protectant will give protection against
seedcorn maggots and seedcorn beetles.

Surface residues from no-till and reduced-tillage sys-
tems may present some problems with the placement
and incorporation of granular soil insecticides applied
at planting. To be most effective, the soil insecticide
should be incorporated into the upper xh inch of soil,
and not just broadcast on the surface. Granules remain-
ing on the soil surface are degraded by sunlight, resulting
in erratic or poor control.

NOTE: Before using Broot, Dyfonate, Mocap, or
Thimet on no-till corn, be sure that soil moisture is low
enough to ensure closing of the seed furrow to prevent
the insecticide granules from contacting the seed. Crop
injury may occur with these products.

Aboveground Insect Pests

Aboveground insects will be more of a problem in
no-till corn than under reduced or conventional tillage.
Corn planted in grass sod or fall-seeded rye is vulnerable
to attack by armyworms. The moths lay eggs on the
grasses during April or early May. After vegetation is
killed by a herbicide, the larvae move to the young corn

10

seedlings and feed on them. Control is justified when
25 percent of the plants are being damaged. Rescue
treatments are effective, but a spray volume of 15 to
20 gallons per acre will improve coverage and control.
Instances of damage to corn by the common stalk borer
have been greater in no-till corn than with other tillage
systems. Moths of this insect deposit their eggs on weeds
in late August and September. When a herbicide is
applied in the spring to no-till corn in fields previously
infested with host weeds, the newly hatched stalk borer
larvae move from the dead vegetation and attack newly
emerging corn plants. Rescue treatments may give er-
ratic control of common stalk borer because the chem-
icals cannot reach the worms inside the stem. To reduce
the potential of stalk borer damage in a subsequent
season, it is essential to have good weed control within
a field during August and September, when moths are
laying eggs.

Potato lea/hoppers may cause moderate to severe dam-
age to the second and third cuttings of alfalfa in all
areas of Illinois. However, population levels are difficult
to predict because the leafhoppers do not survive the
winter in Illinois. They migrate from southern states
into Illinois during May and June.

Damage first appears as a yellow, wedge-shaped area
at the tip of the leaf and is more evident during dry-
weather. Many people confuse the damage with diseases
or nutrient deficiency.

Damage may begin on the new growth as soon as
the first hay crop is removed. Stunting and yellowing
are signs of leafhopper injury. A swarm of leafhoppers
at the time of the first cutting also indicates that there
may be a problem in the new growth. The economic
threshold for leafhoppers varies with the height of the
alfalfa (see Table 4). A treatment is justified when the
number of leafhoppers exceeds the economic threshold.

FORAGE INSECTS

Alfalfa weevils may cause moderate to severe damage
to the first cutting of alfalfa in most areas of Illinois. In
the southern counties, where a lot of egg laying takes
place in the fall, alfalfa-weevil larval damage occurs early
in the spring. Damage to the first cutting in northern
Illinois is more likely to occur if hay harvest is delayed.
Otherwise the injury to alfalfa in the northern counties
will occur on the stubble and new growth of the second
cutting.

Numbers of alfalfa weevils are regulated to a large
extent by winter weather. During a cold, open winter
the mortality rate is high in overwintering weevil pop-
ulations; during mild winters the mortality rate is low.

A parasitic wasp and a fungal disease organism that
attack alfalfa weevil larvae sometimes regulate weevil
numbers in the spring. Although the wasp and the
fungus will be present in alfalfa fields in 1985, we cannot
yet predict their effect on weevil numbers.

Alfalfa growers in southern and central Illinois should
inspect their fields closely in April, May, and June. Early
larval damage appears as pinholes in the growing ter-
minals. As the larvae grow, they skeletonize the leaves,
and damaged fields appear tattered. Growers in northern
Illinois should look carefully for larval damage in May
and June. All growers should examine the stubble after
the first cutting, because larval and adult feeding can
slow or halt new growth. Follow the suggestions in
Circular 1136, "Alfalfa Weevil Pest Management Pro-
gram," to determine the need and proper timing of a
treatment. If this circular is unavailable, a rule of thumb
is to treat when 25 percent of the tips are being
skeletonized. This threshold is 40 percent in northern
Illinois where damage occurs later in the season.

BEAN LEAF BEETLES

Bean leaf beetles overwinter as adults under debris
in fencerows, wooded areas, and other protected sites.
The survival of the overwintering beetles depends on
the winter weather. A mild winter increases the chances
for a large population in the spring. In addition, if
soybeans are planted early, the beetles will establish
themselves early. The availability of soybeans during the
early part of the season is essential for the survival of
bean leaf beetles. The survival of large numbers early
in the season generally means an even larger population
in August. On the other hand, a severe winter and later
planted soybeans will reduce the number of bean leaf
beetles in the spring.

The beetles may cause considerable leaf-feeding in-
jury to double-cropped soybeans and late maturing
soybean varieties. Insecticide treatments are recom-
mended during the critical pod-set and pod-fill stages
when defoliation exceeds 20 percent. The greatest con-
cern, however, is caused by the beetles' pod-feeding
damage, which leaves scars on many pods. These scars
predispose the pods to fungal infections. A treatment is
recommended when 5 to 10 percent of the pods are
damaged.

Table 4. Economic Thresholds for Potato Leafhoppers on
Alfalfa

Alfalfa height
(inches)

Average number of leafhoppers
per sweep of sweep net

0-3

3-6

6-12

12 or taller

0.2
0.5
1.0
1.5

11

CHEMICAL INJURY TO SOYBEANS

There have been instances of phytotoxicity to soy-
beans when organic phosphate soil insecticides were
used. The problems have occurred where growers started
planting soybeans without first emptying the insecticide
boxes. Organic phosphate soil insecticides applied in
soybean fields treated with Sencor or Lexone may cause
injury to a soybean crop, according to information on
the labels.

MANAGING INSECT PESTS IN STORED GRAIN

The following paragraphs describe methods for min-
imizing insect problems in stored grain. For more details
on insecticides, rates, and methods of application, see
Tables 11 and 12.

Remember that insect management for stored grain
depends upon good grain storage practices. Store only
clean, dry grain with a minimum of foreign material
and a moisture content of 13 percent or less. Do not
overfill bins; the levelled grain surface should be at least
8 inches below the lip of the bin. Grain should be cooled
below 50 °F as soon as possible. Do not mix new grain
with old grain. If grain is to be stored one month or
more between May and October, follow the procedures
listed below.

New Grain (Wheat, oats, shelled corn, sorghum, barley,
rye, and sunflower seed)

1. At least 2 weeks prior to filling, thoroughly clean
in, around, and under the empty bin. Clean grain-
handling equipment before harvest and collect the first
few bushels coming through the combine to feed to
livestock. Clean nearby seed storage areas, feed rooms,
hay lofts, and other areas where insects may be present.

2. Two weeks before storage is to begin, spray the
walls, ceiling, and floor of the bin to runoff with 2.0
percent malathion; use 4 ounces of the 50 to 57 percent
EC per gallon of water. Be sure to thoroughly treat
cracks and crevices, above doors, and behind false
partitions. Malathion sprays will not successfully control
insects in grain debris below nonremovable perforated
subfloors. The fumigant chloropicrin (sold as Larvacide
100 and Quasar) will control insects in this subfloor
void. Seal all openings at levels below the perforated
floor, and close and seal all side doors and ventilation
hatches. Pour in chloropicrin (32 ounces per 3,000-
bushel bin) from a ventilation door on the bin roof.
Post warning signs and wait 24 hours before airing out
fumigated space.

Chloropicrin is a restricted-use pesticide.

3. Apply malathion to the grain as it is augered into
the bin. Use 1 pint of malathion 50 to 57 percent EC
in 2 to 5 gallons of water for each 1 ,000 bushels. An
alternative to spray applications is to apply 10 pounds
of 6 percent, 15 pounds of 4 percent, or 30 pounds of

2 percent malathion dust (wheat flour) per 1 ,000 bushels.
Malathion treatments are effective for up to 12 months.
Because high temperatures result in rapid volatilization
and loss of malathion effectiveness, metered malathion
applications at the auger are not recommended if grain
is to be heat dried after it is in the bin.

4. In order to protect grain from Indian meal moth,
which is resistant to malathion, follow either Step A or
Step B.

Step A. Hang one dichlorvos resin strip per 1,000
cubic feet of overspace in enclosed bins and replace the
strips every 6 to 8 weeks. Cover open-top bins with a
raised tarp to retain the vapors from the dichlorvos
resin strips.

Step B. An alternative to the dichlorvos strip is
Bacillus thuringiensis (Dipel, Topside, SOK-BT). Apply it
as a wettable powder (1 pound per 10 gallons of water)
or liquid concentrate (4 pints per 10 gallons of water)
at 0.6 pint finished spray per bushel to the top 4 inches
of grain as it is augered into the bin. A dust formulation
of Bacillus thuringiensis is available and should be applied
at Vz ounce per bushel on the top 4 inches of grain as
it is binned. Level the surface of the grain after treat-
ment.

Although best results are obtained when the B.t. is
applied to the grain as it is going into storage, B.t. can
also be applied after the grain is binned. Apply one-
third of the dosage over the entire surface and rake it
in with a garden rake to a depth of 4 inches. Follow the
same procedure for the second one-third of the dosage,
and rake at a 90-degree angle to the first raking. Apply
the last one-third over the surface and leave it undis-
turbed.

5. To protect grain from infestation by incoming
insects other than Indian meal moth, spray the surface
of the grain with malathion. Add 4 ounces of malathion
50 to 57 percent EC to 1 gallon of water. Apply at a
rate of 2 gallons of finished spray per 1 ,000 square feet.
An alternative is to apply malathion 6 percent dust at
5 pounds, the 4 percent dust at 7.5 pounds, or the 2
percent dust at 15 pounds per 1,000 square feet. Do
not rake this treatment into the surface grain.

6. Cool the grain below 50 °F as soon as possible.
Stored grain insects do not reproduce at temperatures
below 60 °F, and they do not feed when grain temper-
atures drop below 50 °F.

7. Inspect the grain at monthly intervals. Use probes
to monitor temperature, moisture, and insect presence
at several sites and depths.

Soybeans

Clean the bin and grain-handling equipment before
harvest, and treat the walls, ceiling, and floor of the bin
as suggested under "New Grain," Step 2. Soybeans

12

stored at safe moisture levels are attacked only by Indian
meal moth. If soybeans are harvested before October 1
or carried over beyond May 15 of the following year,
follow Step 4 under "New Grain." Aluminum phosphide
can be used to fumigate soybeans if insect infestations
are detected; check the fumigation instructions provided.

Infested Grain

Explore the option of cooling the grain below 50 °F
until you are ready to sell it or feed it to livestock. Also
consider screening the grain and marketing it to avoid
treatment costs. Weigh the loss due to a discount against
the cost of control. Sometimes the most economical
action is to immediately market infested grain.

Where only Indian meal moth infests stored grains,
an alternative to fumigation is to use both the Bacillus
thuringiensis and dichlorvos resin strip treatments as
suggested in Step 4 under "New Grain." Fumigation is
usually necessary if Indian meal moth infestations are
severe.

Where infested grain can be moved to a clean and
sprayed bin, treatment with malathion is an alternative
to fumigation. Apply a spray of malathion to the grain
as it is augered or elevated to the new bin. Use 1 pint
of 50 to 57 percent malathion in 2 to 5 gallons of water
for each 1,000 bushels. Although malathion will not
immediately kill insects that are inside kernels, it will
eventually provide effective control. Also follow Steps
4 through 7 as suggested under "New Grain."

Infested grain that cannot be handled as suggested
should be fumigated. Bins with a capacity of more than
5,000 bushels should probably be treated by a licensed,
professional fumigator. See your county Extension ad-
viser in agriculture for a list of licensed fumigators.

To do your own fumigation, follow these steps:

1. Fumigate only on a calm, warm day when the
grain temperature is above 70 °F. Seal cracks and holes
in the bin, paying particular attention to the base area
around the doors and ventilating fan.

2. Level the surface of the grain, break up any caked
or crusted areas, and remove webbing. The surface level
of the grain should be at least 8 inches below the lip of
the bin.

3. Spray the outside surface of the bin to runoff with
a dilute spray of malathion. Mix 4 ounces of 50 to 57
percent malathion EC per gallon of water.

4. Apply a liquid or solid fumigant. (Methyl bromide,
a gaseous fumigant, can be applied only by professional,
licensed fumigators.) Use 3 to 5 gallons of liquid fu-
migant per 1,000 bushels; use the 5-gallon rate in
wooden bins and flat storages. Common liquid fumigants
are carbon bisulfide + carbon tetrachloride (80:20 mix-
ture), and ethylene dichloride + carbon tetrachloride
(75:25 mixture). Other liquid fumigants also may be
available, but the use of formulations containing ethylene

dibromide (EDB) for grain fumigation is now prohibited.

Place the containers on the grain surface, spacing
them evenly. Loosen the caps slightly, then remove them,
and invert the containers on the surface. Get out of the
bin within 30 seconds to one minute. Follow all directions and
precautions on the label when using a fumigant. Wear pro-
tective clothing and a proper respirator. Have someone watching
you from outside the bin as a safeguard. It is better to apply
the liquid fumigant uniformly over the surface as a
coarse spray if you can do so from outside the bin.

Dry fumigants containing aluminum phosphide (in-
cluding Phostoxin, Detia, Fumitoxin, and Gastoxin) may
be used in place of liquid fumigants. A special applicator
is required to place aluminum phosphide tablets or
pellets in the grain mass. When handling the tablets or
pellets, do not allow water to come in contact with them.
Wear neoprene rubber gloves to prevent perspiration
from coming in contact with the tablets or pellets.
Following application, complete the process of sealing
the bin by tarping the grain surface or tarping over the
bin roof. Tarps may be partially in place prior to adding
the aluminum phosphide to the grain. Although dan-
gerous levels of phosphine gas usually do not develop
above grain for 1 to 2 hours after treatment, this period
can be much shorter if grain temperatures are high.
Follow all label directions and precautions.

NOTE: Anhydrous ammonia is not suggested for
fumigation of stored grains. It is generally ineffective
against insects in stored grain unless concentrations
exceed the level at which grain is blackened from
exposure.

5. Place signs at all entrances warning that the bin
is being fumigated. List the fumigant used and the
name, address, and telephone number of a responsible
person to contact in case of emergency.

6. Bins should remain sealed for 24 hours if liquid
fumigants are used and 72 hours if aluminum phosphide
is used. Air out bins before removing and disposing of
liquid fumigant containers.

7. Protect against reinfestation by following steps 4
through 7 as presented under "New Grain."

Carry-Over Grain

Beginning about May 15 in the southern half of
Illinois and June 1 in the northern half of the state,
warming temperatures speed insect development and
increase the risk of storage problems. Grain not treated
with malathion within the past 12 months should be
treated if grain transfer is possible. Use malathion as a
protectant as directed in Step 3 under "New Grain." If
grain transfer and treatment with malathion is not
possible, monitor temperature, moisture, and insect pres-
ence twice per month from June to October. Where
insects are detected, consider sale or fumigation and
protection as previously discussed under "Infested Grain."

13

Table 5. Field Corn

Insect

Insecticide*

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

Armyworms

Furadan 15G

lb Band, furrow Apply as a planting-time treatment for armyworms in corn planted

no-till in grass sod or small grains.

♦Ambush, *Pounce 0.1-0.2
Dylox Vi-1

*Lannate, *Nudrin lA-Vi

Lorsban 4E lA-l

malathion 1

*Penncap-M '/2-s/i

♦Pydrin 0.1-0.2
Sevin 1

Broadcast

At first migration, or when worms are eating leaves above ear level.

Billbug

Counter 15G
Lorsban 15G
Lorsban 4E

lb

l-2b

2

Band, furrow

Band

Broadcast-PPL

At planting.

Chinch bug

Lorsban 4E

Lorsban 4E

*Pydrin

Sevin

1-1 Vi Broadcast Apply as a postemergence rescue treatment with ground equipment

when damage appears.

lb Spray at base At start of migration from small grains. Use only ground equipment

0.1-0.2b of plant and apply 20 to 40 gallons of finished spray per acre.

2b

Common stalk
borer

Lorsban 4E
*Pydrin

l-Wi

0.15-0.2"

Broadcast Furadan 15G applied at 2-3 lb. a. i. /acre at planting time may provide

early season suppression of common stalk borers. Apply postemergence
sprays when damage first appears. See labels for specific instructions
about effective control.

Corn earworm

*Lannate, *Nudrin V*

*Pydrin 0.1-0.2

Overall spray Justified only in seed corn fields. Several treatments may be needed,
or directed to- Insecticide applications are rarely effective for the control of earworms
ward ear zone in commercial field corn after worms enter ear tips.

Corn leaf aphid

Lorsban 4E

malathion

*Penncap-M

V2-I
1

V2-V4

On foliage Apply during late whorl to early tassel when 50% of plants have light

to moderate infestations and plants are under drouth stress.

Corn rootworm
beetles

diazinon spray

Imidan

Lorsban 4E

malathion

*Penncap-M

Sevin

Vi
Vi

1/2-I
1

V*
1

Overall spray or
directed toward

Before 75% of plants have silked, if there are 5 or more beetles per
plant, and if silk clipping is observed. Only to protect pollination.

ear zone

Corn rootworm
larvae

Broot 15GX
Counter 15G
**Dyfonate20G,4E
**Furadan 15G, 4F
Lorsban 15G
Mocap 15G
Thimet 20G

lb
lb
lb
lb
lb
lb
lb

Band
Band
Band
Band
Band
Band
Band

According to label directions, Mocap 15G should be applied behind
the press wheels of all planters and then incorporated. For John Deere
7000 series planters, place Dyfonate 20G behind the firming wheels
and incorporate. Do not place Broot, Dyfonate, Mocap, or Thimet in
direct contact with the seed. Basal treatments during cultivation with
Counter 15G, Dyfonate 20G, Furadan 15G or 4F, Lorsban 15G or
4E, Mocap 15G, or Thimet 20G are effective in late May or early
June.

Cutworms

Lorsban 15G
Lorsban 4E

lb
1-2

*Ambush, *Pounce

0.1-0.2

Broadcast

Lorsban 4E

1-1 Vi

Broadcast

*Pydrin
Sevin bait

0.1-0.2
1-2

Broadcast
Broadcast

European corn
borer, first

*Ambush, *Pounce
diazinon 14G

0.1-0.2
1

On upper '/s
of plant and

generation

Dipel 10G
Dyfonate 20G
♦♦Furadan 15G.4F

See label
1
1

into whorl

Lorsban 15G

1

*Penncap-M

1

Band Planting-time applications of Mocap 15G will control light to moderate

Broadcast-PPIc infestations of black and sandhill cutworms. Dyfonate 20G applied at

planting time will control light to moderate infestations of black

cutworms. Counter 15G and Furadan 15G applied at planting time

will suppress cutworms.

Apply as a postemergence rescue treatment when 3 percent or more
of the plants are cut in the 2-leaf stage and there are 2 or more
cutworms per 100 plants. At the 4-leaf stage, control is justified if 3
percent or more of the plants are cut and there are 4 or more worms
per 100 plants.

When 50% or more of the plants have fresh whorl-feeding and live
borers are present. Sprays are most effective when directed over the
row, rather than broadcast.

Table 5. Field Corn (continued)

Insect

Insecticide3

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

European corn
borer, second
generation

diazinon 14G 1

Dyfonate 20G 1

**Furadan 15G, 4F 1

Lorsban 15G 1

*Penncap-M 1

On foliage Apply at first hatch when half of the plants have egg masses, or when

cumulative counts, made one week apart, exceed 1 egg mass for every
2 plants.

Fall armyworm

diazinon 14G 1

Dylox 1

*Lannate, *Nudrin Vi

Lorsban 4E 1

On foliage Treat when 35% of plants have whorl damage and if worms are

present. Ground sprays directed over the row are more effective than
broadcast sprays. Treatments to control worms in ear tips are not
effective.

Flea beetles

diazinon spray
Lorsban 4E
*Penncap-M
Sevin

'/2b
lb

'/2b
1"

Over row When leaves on seedling plants are severely damaged and some plants

as spray are being killed.

Grasshoppers

Cygon

diazinon spray
*Furadan 4F
Lorsban 4E
malathion
*Penncap-M
*Pydrin
Sevin

Vi

V*

v*-v*

V*-Vi

i

1/4-3/4
0.1-0.2
V2-V/2

On foliage As needed. The higher rates are suggested for control of adult

grasshoppers.

Hop vine borer None labeled

Postemergence sprays of Pydrin or Lorsban may give some control if
applied when damage first appears.

Japanese beetle Sevin

On foliage During the silking period to protect pollination if less than 75% of

plants are silked and there are 3 or more beetles per ear.

Picnic, sap
beetles

diazinon spray
*Lannate
malathion
Sevin

1

V*

1
1

On foliage

Justified only in seed corn fields when beetles are feeding on ear tips.

Seedcorn
beetles

Counter 15G
Dyfonate 20G
Lorsban 15G
Thimet 20G

lb
lb
lb
lb

Band, furrow
Band
Furrow
Band

At planting.

diazinon

diazinon + lindane

Lorsban 50-SL

See label
See label
See label

On seed
On seed
On seed

Use formulations that are prepared as seed treaters.

Seedcorn
maggots

Counter 15G
Dyfonate 20G
Furadan 15G
Lorsban 15G
Thimet 20G

lb
lb
lb
lb
lb

Band, furrow

Band

Furrow

Furrow

Band

At planting.

diazinon

diazinon + lindane

Lorsban 50-SL

See label On seed Use formulations that are prepared as seed treaters. Seed treatments

See label On seed should be considered for fields that do not receive a soil insecticide

See label On seed at planting.

Sod webworm

None labeled

At time of initial attack, sprays of Sevin or Lorsban may be effective.

Southwestern
corn borer

diazinon 14G
Dyfonate 20G
**Furadan 15G, 4F
Lorsban 15G, 4E
* Pen neap- M
*Pydrin

1-2

1

1

1

1
.1-0.2

On foliage Direct granules over row. Apply when 25% of the plants have egg

masses or larvae on leaves. Early-planted corn usually escapes damage.
Sprays are most effective when directed over the row, rather than
broadcast.

Spider mites

diazinon spray
Di-Syston 15Gd
ethion sprayd
Thimet 20Gd
Trithion

Vt
1
1
1
1

On foliage Begin control if the majority of plants are infested with mites severe

enough to cause some yellowing or browning of the lower leaves
before dent stage.

Table 5. Field Corn (continued)

Insect

Insecticide*

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

Symphylans

Counter 15G
*Dyfonate 4E
Lorsban 15G
Lorsban 4E

lb
2

1-1 '/21

1-2

Band, furrow
Broadcast-PPIc
Band
Broadcast-PPIc

At planting.

Thrips

malathion

1

On foliage

When severe wilting and yellowing of leaves are noticed.

White grubs

Counter 15G
Lorsban 15G
Lorsban 4E
Thimet 20G

lb

l-2b
2

lb

Band, furrow
Furrow

Broadcast-PPIc
Band

At planting. Furadan 15G applied in a 7-inch band or in the seed
furrow will aid in the control of white grubs.

Wireworms

Counter 15G
Furadan 15G
Lorsban 15G
Lorsban 4E
Mocap 15G
Thimet 20G

lb

lb

2b

2

lb

lb

Band, furrow

Band, furrow

Band, furrow

Broadcast-PPIc

Band

Band

Dyfonate 20G applied in a 7-inch band is labeled for suppression of
wireworms.

Woollybear
caterpillars

None labeled

Silk clipping caused by caterpillars does not generally warrant control.

* Use restricted to certified applicators only.

** Liquid formulations of Dyfonate, Furadan, and Mocap are restricted.

* See Table 15 for insecticide restrictions.

b Based on 40-inch row spacing. Increase rates for narrow rows.

c PPI Pre-plant incorporated.

d To be applied only by experienced operators or those wearing protective clothing.

Table 6. Soybeans

Insect

Insecticide2

Pounds of

active
ingredient
per acre Placement

Timing of application, comments

Bean leaf
beetle

*Ambush, *Pounce

Cygon

Lorsban 4E

Orthene

*Penncap-M

*Pydrin

Sevin

0.05-0.1

>/2
'/*

l/2
'/2

0.1

1

On foliage Before bloom: when defoliation reaches 30%, at least 1 cotyledon per

foot of row is destroyed, and there are 5 or more beetles per foot of
row. Bloom to pod fill: when defoliation reaches 20% and there are
16 or more beetles per foot of row. Seed maturation: when 5 to 10%
of the pods are damaged, the leaves are green, and there are 10 or
more beetles per foot of row.

Blister beetles

Cutworms

Sevin 1 On foliage When defoliation reaches 30% before bloom and 20% between bloom

and pod fill.

On foliage Damage occurs when larvae feed on pods. Apply control if populations

exceed 1 per foot of row.

Corn earworm

* Ambush, * Pounce
*Lannate, *Nudrin

0.1

Orthene

1

*Pydrin

0.1-0.2

Sevin bait

Lorsban

*Pydrin

1-2

1
0.1-0.2

Broadcast
Broadcast
Broadcast

Scout as plants are emerging. Treat if 20% of plants are cut and stand
has gaps of one foot or more and cutworms are present.

Grasshoppers

Cygon

'/*

*Furadan 4F

VbM

Lorsban 4E

V*-Vt

Orthene

V*-Vt

*Penncap-M

lA-V*

*Pydrin

0.1-0.2

Sevin

Vi-V/t

On foliage When migration into fields begins and defoliation or pod feeding

reaches economic levels. When defoliation reaches 30% before bloom
and 20% between bloom and pod fill. The higher rates are suggested
for control of adult grasshoppers.

16

Table 6. Soybeans (continued)

Insect

Insecticide3

Pounds of

active
ingredient
per acre Placement

Timing of application, comments

Green clover-
worm

*Ambush, *Pounce

Dipel, Thuricide,
Bactur, SOK (Ba-
cillus thunngiensis)

Lorsban 4E

Orthene

*Penncap-M

*Pydrin

Sevin

0.05-0.1
See label

Vi

Vi

Vi

0.05-0.1
Vt

On foliage When defoliation occurs during blooming, pod set, and pod fill. Usually

requires 12 or more half-grown worms per foot of row and 20%
defoliation to justify treatment.

Japanese
beetle

*Penncap-M
Sevin

»/4-l

1

On foliage

When defoliation reaches 20% during bloom and pod fill.

Loopers

* Ambush, * Pounce 0.05-0.1
Orthene Vi-\

♦Pydrin 0.1-0.2

Thuricide, Dipel, See label
Bactur, SOK {Ba-
cillus thuringiensis)

On foliage When defoliation reaches 30% before bloom and 20% between bloom

and pod fill.

Mexican bean * Ambush, *Pounce 0.05-0.1

beetle Cygon Vi

*Furadan 4F l/i

Lorsban 4E Vi

Orthene Vi

*Penncap-M Vt

♦Pydrin 0.05-0.1
Sevin 1

On foliage When defoliation reaches 30% before bloom and 20% between bloom

and pod fill.

Potato
leafhopper

*Ambush, *Pounce

*Penncap-M

*Pydrin

Sevin

0.05-0.1

Vi
0.05-0.1

1

On foliage When leafhoppers are numerous and the edges of the leaves appear

burned.

Saltmarsh *Lannate, *Nudrin Vi

caterpillar Lorsban 4E Vi

*Pydrin 0.05-0.1

On foliage When defoliation reaches 30% before bloom and 20% between bloom

and pod fill.

Seedcorn
maggot

diazinon

diazinon + lindane

See label On seed
See label On seed

At planting time. Use formulations that are prepared as seed treaters.

Spider mites

Cygon
Lorsban 4E
*Penncap-M
Trithion

Vi
Vi
Vi

Vi-v<

On foliage

As needed on field margins or entire field.

Stink bugs

Lorsban 4E

Orthene

*Penncap-M

*Pydrin

Sevin

1

S/4-l

Vi-%

0.1-0.2

1-1 Vi

On foliage When adult bugs or large nymphs reach 1 per foot of row during pod

fill.

Thistle
caterpillar

Sevin

2

On foliage

When defoliation reaches 30% before bloom and 20% between bloom
and pod fill.

Thrips

*Penncap-M
Sevin

Vt-V*
1

On foliage

If seedlings are being seriously damaged and some plants are being
killed.

Webworms

Sevin

1

On foliage

When defoliation reaches 30% before bloom and 20% between bloom
and pod fill.

Whitefly

None labeled

High infestations are occasionally present on double-crop soybeans,
but are rarely economic.

Woollybear
caterpillars

Lorsban 4E
* Pounce
*Pydrin

Vi-\
0.1
0.1

When defoliation reaches 30% before bloom and 20% between bloom
and pod fill. Sprays of Ambush or Penncap-M may also be effective.

* Use restricted to certified applicators only. * See Table 1 5 for insecticide restrictions.

Spraying blossoming soybeans can be extremely hazardous to bees.
Coordinate with local beekeepers before applying sprays.

Table 7. Alfalfa and Clover

Insect

Insecticide'6

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

Alfalfa weevil
(spring treat-
ment for
larvae)

*Furadan 4F
Imidan
Lorsban 4EC
malathion +

methoxychlor
*Penncap-M
*Supracide

V*-Vi

1

1

2 qt. per

acre

Vi

Vi

On foliage Refer to Circular 1136. Or when 25% of tips are being skeletonized

and if there are 3 or more larvae per stem, treat immediately. Do not
apply sprays during bloom. Instead, cut and remove the hay. Two
treatments may be necessary on first cutting. Watch regrowth for signs
of damage, and treat if feeding damage is apparent.

To avoid injury to bees, do not spray alfalfa during bloom or if weeds are blooming.

Alfalfa weevil
adults

*Furadan 4F
Imidan
Lorsban 4EC
*Penncap-M

V4-1

1
1

As a stubble spray.

Aphids

Cygon

*Furadan 4F

*Lannate

Lorsban 4EC

malathion

*Penncap-M

*Supracide

V*
'/«

V*
Vi
1
'/*

On foliage When aphids average 100 or more per sweep and lady beetle larvae

and adults, parasites, and diseases are not abundant.

Avoid treatments when plants are blooming.

Blister beetles

Sevin

1

On foliage

Although blister beetles rarely cause economic damage to alfalfa, their
presence in hay could injure horses if the horses ingest the beetles.

Clover leaf
weevil

malathion

1

On foliage

When larvae are numerous (5 or more per crown) and leaf feeding is
noticeable, usually in early to mid-April.

Cutworms

Dylox

Lorsban 4EC
Sevin

1

l'/2

On foliage

As needed on regrowth of second cutting.

Fall armyworm

Dylox

*Lannate, *Nudrin

Lorsban 4EC

1

Vt
1

On foliage

Usually in late summer or early fall on new seedlings or established
stands.

Grasshoppers

Cygon
diazinon spray

V*-Vi

*Furadan 4F

Vs-V*

Lorsban 4EC

V*-Vi

*Penncap-M

V4-K

Sevin

\-\Vi

Leafhoppers

Cygon
*Furadan 4F

Vi

Vi

Lorsban 4EC

'/2-1

*Penncap-M

Vi-'A

Sevin

l

♦Supracide

Vi

On foliage When grasshoppers are small and before damage is severe. The higher

rates are suggested for control of adult grasshoppers. Avoid treatments
when plants are blooming.

On foliage

Treatment is justified at these combinations of alfalfa height and
leafhopper numbers:
Alfalfa height Leafhoppers
(inches) per sweep

0-3

0.2

3-6

0.5

6-12

1.0

12 or taller

1.5

Avoid treatments when plants are blooming.

Plant bugs

Cygon
Dylox
*Furadan 4F

V*-Vi

1
1

Lorsban 4EC

Vt-l

*Penncap-M
Sevin

Vi-y*
i

Lorsban 4EC

'/2-1

malathion +

2 qt. per

methoxychlor
malathion

acre
1

*Penncap-M

Vi-V*

On foliage When tip damage is obvious and nymphs and adults are numerous.

Avoid treatments when plants are blooming.

Spittlebug

On foliage When spittle masses are found and nymphs average more than 1 per

stem.

Avoid treatments when plants are blooming.

Table 7. Alfalfa and Clover (continued)

Insect

Insecticide3,6

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

Webworms

Dylox
malathion +

methoxychlor
Sevin

1

2 qt. per

acre

1

On foliage

If damage appears.

* Use restricted to certified applicators only. * See Table 15 for insecticide restrictions.

b Before applying insecticides, be certain to clean all herbicides out of equipment. During pollination, apply very late in day or, if possible,

avoid application during bloom.
c Young, tender, rapidly growing alfalfa may show some phytotoxic symptoms when treated with Lorsban 4E.

Spraying blossoming alfalfa can be extremely hazardous to bees.
Coordinate with local beekeepers before applying sprays.

Table 8. Grain Sorghum

Pounds of

active
ingredient

Insect

Insecticide'

per acre

Placement

Timing of application, comments

Chinch bug

Lorsban 4Eb
Sevin

1
2

At plant base

Use only ground equipment and apply 20 to 40 gallons of finished
spray per acre.

Corn earworm

*Lannate, *Ni
Sevin

jdrin

1-2

Over row

When there is an average of 2 worms per head.

Corn leaf aphid

Cygon
Lorsban 4Eb
malathion

V*-Vi
1

Over row

Corn leaf aphids rarely cause economic damage unless populations are
heavy and drouth conditions exist.

Cutworms

Lorsban 4Eb

1

Broadcast

When seedling plants are being cut.

Fall armyworm

*Lannate, *Ni
Lorsban 4Eb
Sevin

idrin

Vt
1

Wt

Over row

When there is an average of 2 worms per head. Leaf feeding or whorl
damage is seldom economic.

Grasshoppers

Cygon
Lorsban 4Eb
Sevin

Vt

V*-Vt

Over row

As needed. The higher rates are suggested for control of adult
grasshoppers.

Greenbug

Cygon

diazinon spray
Lorsban 4Eb
malathion

lA-Vt Over row

Vi

'/4-'/2
1

When greenbug damage is sufficient to cause death of more than 2
normal-sized leaves before the hard-dough stage. CAUTION: Some
sorghum varieties are sensitive to organophosphate insecticides.

Counter 15G
Furadan 15G
Thimet 20G

1-2C
lc
lc

Band

Band, furrow

Band

At planting.

Sorghum midge Cygon lA

diazinon spray lA

*Lannate, *Nudrin V*

Lorsban 4Eb '/«

Over row Apply during bloom when 50% of heads have begun to bloom and

there are 1 or more midge adults (flies) per head.

Webworms *Lannate, *Nudrin Vt

Lorsban 4Eb 1

Sevin 1-2

Over row

When 5 or more larvae per head are found.

Yellow sugar-
cane aphid

Cygon
Lorsban 4Eb

Vt
Vt-\

Over row Treatment should be applied at first sign of damage to seedling

sorghum; 5 to 10 aphids per leaf.

* Use restricted to certified applicators only.

1 See Table 15 for insecticide restrictions.

b To avoid phytotoxicity, do not treat plants that are under extreme heat and drouth stress.

c Based on 40-inch row spacing. Increase rates for narrow rows.

19

Table 9. Small Grains (Barley, Oats, Rye, Wheat)

Insect

Insecticide*

Pounds of

active

ingredient

per acre

Placement

Timing of application, comments

Armvworm

Dylox

*Lannate, *Nudrin

*Penncap-M

Sevin

Vt-1

V*-Vt

Vt-V*

1

On foliage When there are 6 or more armyworms per linear foot of row and before

extensive head cutting occurs. Do not use Dylox or Penncap-M on rye.

Fall armvworm

Dylox
Sevin

1 On foliage During fall when damage to new growth is apparent. Do not use

1-1 !/2 Dylox on rye.

Grasshoppers

Cygon

*Furadan 4F
malathion
* Penncap-M
Sevin

%
Vs-V*

1
lA-%
V2-W2

On foliage During fall when damage is apparent, treat field borders and noncrop

areas to stop migration. The higher rates are suggested for control
of adult grasshoppers. Do not apply Penncap-M to rye.

Greenbug,
English grain
aphid, oat bird-
cherry aphid

Cygon
malathion
* Penncap-M

lA-V»

1

'/4-'/2

On foliage Aphids damage plants indirectly by transmitting disease. Once yellow-

ing is noticeable, it is usually too late to treat. Use Cygon on wheat
only. Do not apply Penncap-M to rye.

Variegated
cutworm

Dylox

As needed. Do not use Dylox on rye.

Wheat stem
maggot

None

No chemical control. Damage shows as white heads when field is still
green.

* Use restricted to
a See Table 1 5 for

certified applicators only,
insecticide restrictions.

Table 10. Grass Pasture

Insect

Insecticide2

Pounds of

active
ingredient
per acre Placement

Timing of application, comments

Armyworms

Dylox
malathion
* Penncap-M
Sevin

1
1%

1

On foliage As needed. Sevin and Dylox may be applied without removal of grazing

livestock.

Do not apply when weeds are blooming.

Grasshoppers

diazinon spray
malathion
* Penncap-M
Sevin

1

'/2-ll/2

On foliage As needed. The higher rates are suggested for control of adult

grasshoppers.

Do not apply when weeds are blooming.

* Use restricted to certified applicators only.
' See Table 15 for insecticide restrictions.

20

Table 11. Stored Grain (Corn, Wheat, Oats)

NOTE: Corn, sorghum, and sunflower seed need not be treated if harvested after October 1 unless they are to be carried
over after May 15 the following year. Wheat, oats, barley, and rye should be treated if they are to be held for one
month or more in storage after harvest.

Insect

Insecticide
and dilution

Dosage

Placement

Suggestions

Angoumois grain
moth (earcorn)

malathion 57% E.C.
4 oz. per gal. water

Apply to runoff

Spray surface
and sides about
May 1 and
August 1

Plant tight husk varieties. Store as shelled corn
to avoid all but surface damage by Angoumois
grain moth.

Indian meal moth

dichlorvos 20%
(DDVP, Vapona)
plastic resin strip

Bacillus thuringiensis
dust 4,000 units per mg.

Bacillus thuringiensis
WP 16,000 units per mg.
1 lb. in 10 gal. water

Bacillus thuringiensis
LC 4,000 units per mg.
4 pt. in 10 gal. water

1 strip per 1 ,000 Attach to
cubic feet of space ceiling or
above grain mass side wall

Vi oz. per bu.
(See Table 12)

0.6 pt. per bu.
(See Table 12)

0.6 pt. per bu.
(See Table 12)

Apply to top
4 inches of grain

Apply to top
4 inches of grain

Apply to top
4 inches of grain

Clean and spray bin with 2.0% malathion to runoff
before storage. Store only clean, dry grain. Where
infestations develop, remove webbing before
treating.

Install at storage or by May 15. Replace every 6-
8 weeks between May and October. Strips are
effective only in enclosed bins; they will control
adult moths, not eggs or larvae. Complete control
requires 3-6 weeks. Fumigate if immediate con-
trol is necessary. Dichlorvos strips are also regis-
tered for use in bins containing soybeans.

Bacillus thuringiensis (B.t.) controls only larvae; it
must be ingested. Formulations include Dipel,
Topside, and SOK-BT Control may require 3-6
weeks. Apply to grain as it is augered into bins
or incorporate by raking once grain is stored. To
rake in, apply V$ of total amount and rake in 4
inches deep; then apply another V* of the total
rate and rake at right angles to initial incorpo-
ration. Apply final Vs to the surface without rak-
ing. B.t. also is registered for use in soybeans.

GENERAL

Internal and

external feeders
Rice and granary

weevils
Flat grain beetle
Saw-toothed

grain beetle
Rusty grain beetle
Foreign grain beetle
Cadelle beetle
Flour beetles

malathion 57% E.C.
1 pt. per 2-5 gal.
water

2-5 gal. per
1,000 bu.

malathion 6%
wheat flour dust
malathion 4%
wheat flour dust
malathion 2%
wheat flour dust

10 lb. per
1,000 bu.
15 lb. per
1,000 bu.
30 lb. per
1,000 bu.

Spray uniformly
as grain is
binned. After
binning apply 2
gallons per 1,000
square feet over
the surface.

Apply over grain
in combine hop-
per or uniformly as
grain is binned.
After binning,
apply 5 pounds of
6%, 7.5 pounds of
4%, or 15 pounds
of 2% per 1,000
square feet over
the surface.

Clean and spray bin with 2.0% malathion to runoff
before storage. Store only clean, dry grain.

Do not apply malathion prior to heat-drying of
grain, because high temperatures cause rapid mal-
athion vaporization and loss of effectiveness. Mal-
athion will not control Indian meal moth.

Fumigants:

Use extreme caution and follow all label directions
when handling fumigants. Seal bin openings below
the grain surface before fumigating. Grain surface
should be level and at least 8 inches below the
lip of the bin.

21

Table 11. Stored Grain (Corn, Wheat, Oats) (continued)

Insect

Insecticide
and dilution

Dosage

Placement

Suggestions

GENERAL

(continued)

Liquids (Carbon bisulfide
plus carbon tetrachloride
and ethylene dichloride
plus carbon tetrachloride
are common liquid fu-
migants.)

♦Aluminum phosphide
(including Phostoxin, De-
tia, Fumitoxin, and Gas-
toxin)

* Methyl bromide

(gas)

3-5 gal. per
1,000 bu.

1 80 tablets or
300 pellets per
1,000 bu.

20 lbs. per
10,000 bu.

On surface; re-
peat if necessary.

Uniformly
throughout

Inject

Apply under calm conditions when grain temper-
ature is at least 70 °F. Air out the bin 24 hours
after fumigant application.

Apply when grain temperature is at least 60 CF.
After application, cover the grain surface with
plastic tarp and seal the tarp to bin walls. Leave
the bin sealed for 3 days, then air out.

METHYL BROMIDE IS TO BE APPLIED ONLY
BY LICENSED, PROFESSIONAL FUMIGA-
TORS.

* Use restricted to certified applicators only.

Table 12. Amount of Bacillus thuringiensis (B.t.) to Apply

Bin

diameter

(feet)

Bushels in

top 4 inches

of grain

Amount of B.t.

wettable powder (lb.)

and water (gal.) needed

Amount of B.t. liquid

concentrate (oz.)

and water (gal.) needed

Amount of B.t.
dust (oz.) needed

8

13

0.1/1

6.5/1

6.5

12

30

0.25/2.5

14.5/2.5

15

16

53

0.4/4

26/4

27

20

84

0.6/6

39/6

42

24

120

0.9/9

58/9

60

28

163

1.25/12.5

80/12.5

82

32

214

1.6/16

103/16

107

36

336

2.5/25

160/25

168

40

415

3.1/31

198/31

208

48

478

3.6/36

230/36

239

Table 13. Noncrop Areas

Insect

Insecticide'

Pounds of

active
ingredient
per acre Placement

Timing of application, comments

Grasshoppers

diazinon spray
malathion
*Pydrin
Sevin

V* On foliage When grasshopper nymphs average 15 to 20 per square yard along

1 roadsides and fence rows. The higher rates are suggested for control

0.05-0.1 of adult grasshoppers. Do not spray areas adjacent to water or where

Vz-\Vi runoff is likely to occur. Apply treatments while hoppers are small

and before they migrate into row crops.

* Use restricted to certified applicators only. a See Table 15 for insecticide restrictions.

Table 14. Sunflowers

Pounds of

active
ingredient

Insect

Insecticide"

per acre

Placement

Timing of application, comments

Armyworm

Sevin

1 Vi-2

Over row

When defoliation reaches 25%.

Cutworms

Sevin
Lorsban 4E

l'/2
1-1 Vt

Over row

When 10% of the seedlings are damaged.

22

*. Jt

Table 14. Sunflowers (continued)

Stem weevil

*Furadan 4F
Lorsban 4E
Sevin
*Supracide

Pounds of

active
ingredient

Insect

Insecticide3

per acre

Placement

Timing of application, comments

Fall armyworm

Sevin

1 lA-2

Over row

When defoliation reaches 25%.

Grasshoppers

*Furadan 4F
Lorsban 4E
Sevin

1-1V2

Over row

When defoliation reaches 25%.

1-2

Over row

When there are 2 or more beetles per plant.

Sunflower

*Furadan 4F

V*-V*

Over row

When defoliation reaches 25%.

beetle

Lorsban 4E
Sevin

>/2-3/4

1-2

Sunflower

*Furadan 4F

Vi

Over row

Apply first treatment when a field has reached 20 to 25% bloom and

moth larvae

Lorsban 4E
*Supracide

moths are present.

* Use restricted to certified applicators only. a See Table 15 for insecticide restrictions.

Spraying blossoming sunflowers can be extremely hazardous to bees.
Coordinate with local beekeepers before applying sprays.

Table 15. Limitations in Days Between Application of the Insecticide and Harvest of Crop and Restrictions on Use of
Insecticides for Field Crop Insect Control (These are only guidelines — read the label for more detailed information)

(Blanks denote that the product may not be labeled or suggested for that specific use in Illinois)

Worker

re-entry

time (days)3

Field corn

Grain

Ensilage

Grain
Sorghum

Forage crops

Alfalfa

Clover

Pasture

*Ambush (permethrin)ab

A

A

Broot (trimethacarb)

90

90

Counter (terbufos)

B

30,C

D

. . .

Cygon (dimethoate)b

14,E

14,E

28,E

10.F

Diazinon

B

10

7

7

7

0

Dipel (Bacillus thuringiensis)

B

B

**Di-Syston (disulfoton)ab

40

40

. . .

**Dyfonate (fonofos)

30

30

Dylox (trichlorfon)

G

G

0,G

0,G

0.G

Ethion

1

50, H

50,H

**Furadan (carbofuran)a,b

14c

30.IJ

30.IJ

75

K

Imidan (phosmet)

14

14

7,F

**Lannate (methomyl)ab

B

3

14

7

Lorsban (chlorpyrifos)

35, L

14.L

60.M

21.N

Malathion

. . .

5

5

7

0

0

0

Methoxychlor

7

7

**Mocap (ethoprop)

B

B

**Nudrin (methomyl)ab

. . .

B

3

14

7

*Penncap-M (microencapsulated

12

12

15

15

methyl parathion)*,b

* Pounce (permethrin)ab

. . .

A

A

. . .

*Pydrin (fenvalerate)ab

21, P

21, P

Sevin (carbaryl)

0

0

21

0

0

0

*Supracide (methidathion)ab

Thimet (phorate)

Trithion (carbophenothion)ab

30, R
B

30.R
21.S

10,Q

23

Table 15. Limitations (continued)

Worker

re-entry

time (days)a

Barley

Oats

Rye

Wheat

/beans

Sunflowers

21,T

21

0

21.V

28,W

14

28,X

42,Y

0

14

. . .

14.Z

20.AA

21,T

21,BB

0

60

♦Ambush (permethrin)a-b

Cygon (dimethoate)b

Dipel, Thuricide, Bactur, SOK

(Bacillus thuringiensis)
Dylox (trichlorfon)
**Furadan (carbofuran)ab
**Lannate (methomyl)ab
Lorsban (chlorpyrifos)
Malathion

**\udrin (methomyl)ab
Orthene (acephate)
*Penncap-M (microencapsulated

methyl parathion)a,b
♦Pounce (permethrin)ab
*Pydrin (fenvalerate)ab
Sevin (carbaryl)
*Supracide (methidathion)ab
Trithion (carbophenothion)ab

21
U

7

7

7

15

21
U

7

7

7

15

60

21
U

7

7
7

15

21.CC

50.Z

7,Z

Read the label for more detailed information.

A. Apply prior to ear formation.

B. No specific restriction when used as recommended.

C. Only 1 postemergence incorporated treatment or 1 cultivation-
time treatment may be used in addition to treatment at planting
time.

D. Only one application per year may be used.

E. Make no more than 3 applications per year.

F. Apply only once per cutting; do not apply during bloom.

G. Three applications may be made per season on corn, and 3
applications may be made per cutting of alfalfa or grasses. Can be
applied up to harvest.

H. Do not make more than 1 application after ear formation. Do
not feed treated foliage to livestock.

I. Do not make a foliar application if Furadan 15G was applied at
more than 8 ounces per 1,000 linear feet of row (6.7 pounds per
acre with 40-inch row spacing) at planting. Do not make more than
2 foliar applications of Furadan 15G per season.
J. Do not make more than 2 applications of Furadan 4F per season
at the 1V2-2 pint use rate. Do not make more than 4 applications
per season at the 1 pint use rate. Do not apply on seed corn less
than 14 days prior to detasseling or rogueing. If prolonged, intimate
contact will result, do not reenter treated field within 14 days of
application without wearing proper clothing.

K. Make no more than 2 applications per season. Do not apply more
than once per cutting. Do not use more than 1 pint per acre in the
second application. Apply only to fields planted to pure stands of
alfalfa. When using no more than Vi pound per acre, allow 7 days
between application and harvest. When using XA to Vi pound per
acre, allow 14 days between application and harvest. When using Vt
to 1 pound per acre, allow 28 days between application and harvest.
Do not move bees to alfalfa fields within 7 days of application.
L. For soil insect control, do not exceed the equivalent of 16 ounces
of Lorsban 15G per 1,000 feet of row or 13.5 pounds of Lorsban
1 5G per acre per crop season. For foliar insect control, do not exceed
the equivalent of 16 ounces of Lorsban 15G per 1,000 feet of row

or 13 pounds of Lorsban 15G per acre per crop season. Do not

apply more than a total of 15 pints of Lorsban 4E per acre per

season. Do not allow livestock to graze in treated areas nor harvest

treated corn silage as feed for meat or dairy animals within 14 days

after last treatment. Do not feed treated corn fodder to meat or

dairy animals within 35 days after last treatment.

M. The treated crop is not to be used for forage, fodder, hay, or

silage within 30 days after application of 1 pint of Lorsban 4E per

acre or within 60 days after application of rates above 1 pint per

acre. Do not treat sweet varieties of sorghum. Do not apply more

than 3 pints of Lorsban 4E per acre per season.

N. Do not apply more than once per cutting. Do not cut or graze

treated alfalfa within 14 days after application of 1 pint of Lorsban

4E per acre, nor within 21 days after application of rates above 1

pint per acre. Do not make more than 4 applications per year.

P. Do not exceed 1.0 pound of active ingredient per acre per season.

Q. Make no more than 1 foliage and 1 stubble application per alfalfa

cutting.

R. Do not make more than one application over the plant.

S. Do not make more than one application per season.

T. Do not feed or graze livestock on treated plants. Do not exceed

0.8 lb. a.i. per acre per season.

U. Apply before heads emerge from boot. Do not make more than

2 applications per season. Do not feed treated forage to livestock.

V. Do not use Furadan 4F as a foliar application if Furadan 10G,

Furadan 15G, Furadan 4F was applied to soybeans at planting time.

Do not make more than 2 foliar applications per season. Do not

graze or feed foliar-treated forage to livestock or cut for silage or

hay.

W. No more than 4 applications per season.

X. Do not apply more than 6 pints of Lorsban 4E per acre or 3

pounds of chlorpyrifos (active ingredient) per acre per season. Do

not apply last 2 treatments closer than 14 days apart. Do not allow

livestock to graze in treated areas nor otherwise feed treated soybean

forage to meat or dairy animals within 14 days after application. Do

24

Table 15. Limitations (continued)

not feed straw from treated soybeans to meat or dairy animals within
28 days after application. On determinate soybeans do not apply
more than one application after pod set.

Y. Do not apply more than 9 pints of Lorsban 4E per acre per
season. Do not allow livestock to graze in treated areas.

Z. Do not graze or feed treated crop to livestock.

AA. Do not make more than 2 applications per season.

BB. Do not feed or graze livestock on treated plants. Do not exceed

0.8 pound active ingredient per acre per season.

CC. Do not make more than 2 applications after grain heads emerge

from boot.

* Use restricted to certified applications only.

** Liquid formulations are restricted.

' Workers should be warned in advance of treatments. Workers may
not enter fields treated with the insecticides without wearing protec-
tive clothing for the intervals indicated. They may not enter a field
treated with other insecticides without protective clothing until the
spray has dried or the dust has settled. Protective clothing includes
a hat, long-sleeved shirt, full length pants, and shoes and socks.
b Sprays to be applied only by experienced operators wearing proper
protective clothing.

c Do not apply Furadan 4F on seed corn less than 14 days prior to
detasseling or rogueing. If prolonged intimate contact will result, do
not reenter field treated with Furadan 4F within 1 4 days of application
without wearing proper protective clothing.

Table 16. Relative Toxicities of Commonly Used Agricultural Insecticides

Toxicity to mammals3

Toxicity to

Acute

Acute

Trade name

Chemical name

oral

dermal

Birds

Fish

Bees

♦Ambush

permethrin

low

low

low

very high

high

Broot

trimethacarb

moderate

low

Counter

terbufos

high

high

high

very high

Cygon

dimethoate

moderate

moderate

moderate

very low

high

Diazinon

diazinon

moderate

moderate

high

high

high

Dipel, Bactur,

Topside,

Bacillus thuringiensis

very low

very low

very low

very low

very low

Thuricide, !

SOK

**Di-Syston

disulfoton

high

high

moderate

moderate

**Dyfonate

fonofos

high

moderate

moderate

Dylox

trichlorfon

low

low

low

very low

low

Ethion

ethion

high

high

low

very low

** Furadan

carbofuran

high

moderate

moderate

moderate

high

Imidan

phosmet

moderate

low

low

high

**Lannate, **Nudrin

methomyl

high

moderate

low

high

Lorsban

chlorpyrifos

moderate

moderate

moderate

very high

high

Malathion

malathion

low

low

low

moderate

high

Methoxychlor

methoxychlor

low

low

very low

very high

low

* Methyl parathion

methyl parathion

high

high

moderate

very low

high

**Mocap

ethoprop

moderate

high

moderate

moderate

Orthene

acephate

moderate

moderate

moderate

low

high

*Penncap-M

microencapsulated
methyl parathion

moderate

low

moderate

very low

high

* Pounce

permethrin

low

low

low

very high

high

*Pydrin

fenvalerate

moderate

low

low

very high

very high

Sevin

carbaryl

low

low

very low

very low

high

*Supracide

methidathion

high

moderate

moderate

high

high

Thimet

phorate

high

high

moderate

very high

moderate

Trithion

carbophenothion

high

high

high

very high

moderate

* Use restricted to certified applicators only.
** Liquid formulations are restricted.

* Relative toxicities based on acute oral and acute dermal LD50 values of technical insecticide. Toxicities of formulated materials vary.

Always read the label
before applying insecticides.

25

NOTES

26

NOTES

27

Prepared by Kevin L. Steffey, Donald E. Kuhlman, Stephen P. Briggs, and Richard A. Weinzierl, Extension
Entomologists.

Issued in furtherance of Cooperative Extension work, Acts of May 8 and June 30, 1914, in cooperation with the U.S. Department of Agriculture. WILLIAM R.
OSCHWALD, Director, Cooperative Extension Service, University of Illinois at Urbana-Champaign. The Illinois Cooperative Extension Service provides equal
opportunities in programs and employment.

15M— 10-84— 60237— zmh

t HE

UNIVERSITY OF ILLINOIS-URBANA

Q.630.7IL6C C005

CIRCULAR URBANA, ILL.
899 REV. 1985

3 0112 019541207