Prepared: December, 2003
Production Regions:
Figure 1.Leading wheat-producing counties in North Carolina in 2002 (shaded in green).
Leading sorghum-producing counties in North Carolina in 2002 (shaded in green).
Leading oat-producing counties in North Carolina in 2002 (shaded in green).
Leading barley-producing counties in North Carolina in 2002 (shaded in green).
Production Practices:
Most small grains are grown under conventional tillage with no-till acreage increasing slightly every year. Wheat planting dates vary from late September to early November depending upon region. Other planting dates expand this time frame by a week on each extreme.Frost and Hessian flies are factors in planting time.
Soil types vary greatly across the regions and irrigation is generally not used. At-plant nitrogen is usually needed with additional added as needed. Fifteen to 30 pounds of nitrogen per acre are needed.Liming is required based on soil testing.The target pH is 6.0 for mineral soils, 5.5 for mineral-organic soils, and 5.0 for organic soils. Animal waste is sometimes used in small grain fertilization. Regional differences include soil types, temperature and planting dates, Hessian fly pressure, fertilization, and liming requirements.Poorer soil type regions may utilize grains only for crop rotation purposes and on-farm livestock use. Production is much different from that in Midwestern states.
Current North Carolina Cooperative Extension Service recommendations for pesticide use on small grains are provided in the following tables in the North Carolina Agricultural Chemicals Manual:
Table 5-3. Insect Control in Grain Sorghum (http://ipm.ncsu.edu/agchem/chptr5/503.pdf)
Table 5-4. Insect Control in Small Grains (http://ipm.ncsu.edu/agchem/chptr5/504.pdf)
Table 6-1. Foliar Fungicides for Wheat Leaf Disease Control (http://ipm.ncsu.edu/agchem/chptr6/601.pdf)
Table 6-2. Seed Treatment for Wheat Foliar Disease Control (http://ipm.ncsu.edu/agchem/chptr6/601.pdf)
Table 8-1. Chemical Weed Control in Wheat, Barley, Oats, Rye, and Triticale(http://ipm.ncsu.edu/agchem/chptr8/806.pdf)
Table 8-1. Chemical Weed Control in Sorghum (http://ipm.ncsu.edu/agchem/chptr8/807.pdf)
Table 8-21. Weed Response to Herbicides - Small Grains (http://ipm.ncsu.edu/agchem/chptr9/909.pdf)
October: Worker on a tractor makes three passes over the field for
tillage. In no-till wheat worker makes one pass over the field to
bush-hog, and then a second pass over the field to spray a burn-down. In all
tillage systems, one more pass is made to apply fertilizer.
The cereal leaf beetle (CLB) is North Carolina's most important insect pest
of small grains. Because CLB is a pest early in the growing season when weather
conditions can be quite variable, timing of control measures can be difficult.
The key to managing this pest lies in understanding its biology in North
Carolina and using this information along with field observations to determine
when and where treatment may be necessary. New, but labor-intensive treatment
thresholds, are available to growers.
Adult cereal leaf beetles overwinter in protected areas such as ground litter
or debris along the edges of fields. They usually appear in small grain fields
around mid-April but may appear earlier, particularly with mild winter
temperatures.The appearance of adults indicates that egg laying will begin in 7
to 10 days. Adult feeding at this time has little impact on the plants. Peak egg
laying usually occurs in late April to early May.The eggs hatch in a few days
into slug-like yellow larvae that cover their bodies with a black globule of
mucus and fecal matter as they grow. The major damage to small grains results
from larval feeding on young leaves, especially the flag leaf, which is critical
to proper grain head filling.As is the case with many insect pests, temperatures
and weather greatly influence the insect's activity, which in turn affects our
ability to manage it. Oats are slightly more susceptible to CLB than the other
grains.
Insecticides:
There are four species of aphid commonly found in grains in North
Carolina.The corn leaf aphid is found on a variety of grains and grasses. With
this aphid, injury seldom reaches economic levels.The greenbug is also found on
a variety of grain hosts and can cause discoloration and stunting of plants due
to injected toxins. Fortunately, it is not common in large numbers.
The two predominant species, bird cherry-oat aphid and English grain aphid do
not inject toxins and plants appear to tolerate large infestations to foliage
without economic loss. Heavy grain head feeding, especially by English grain
aphid may reduce yields and populations should be monitored.
It is the spread of barley yellow dwarf virus (BYDV) by aphids, however, that
concerns growers the most. Aphids infest grain in the fall and are active as
long as temperatures remain above 50 degrees F, even when they are exposed to
periodic freezing temperatures. All grains to some extent, but early-planted
small grains in particular, are at risk of infection by BYDV if fall aphid
populations are actively migrating into and within fields. Therefore, very early
planting is discouraged, especially on farms where BYDV has been a problem.
Thresholds for treating aphids in the fall are much lower than in spring. Early
infection with BYDV (i.e., infection in the fall) may suppress yield
significantly, whereas the spread of BYDV in the spring may produce relatively
little yield loss.
In prior years, growers sometimes used Di-Syston at planting time on
early-planted small grains or when spraying fall aphids if populations exceeded
the threshold. This method may help to improve yield, however, tests have shown
poor correlation between BYDV suppression and fall insecticide treatments.
Gaucho (imidacloprid) and Cruiser (thiamethoxam) seed treatment have shown to
reduce early aphid feeding and hence BYDV infection. Late planting seems to have
a positive effect at reducing BYDV infection.
Insecticides:
Insecticides are not used for aphids in normal years. A few growers may treat
for aphids in occasional years.
The armyworm (or true armyworm) occurs across the state, but economic
infestations in small grains have usually been confined to the middle and
northern tidewater regions. In recent years, as farmers continue to grow thicker
stands of leafy grains, armyworms have become more difficult to control with
insecticides because of coverage and weather problems.Consequently, farmers are
advised to time insecticide applications to coincide with armyworm activity and
to use higher application volumes (5 gallons per acre, by air) in thick
grains.Armyworms are nocturnal and active in temperatures above 60 degrees F.
Treating in the late afternoon on warmer days may be beneficial.
Insecticides:
Normally, insecticides are not used. Three to five percent of growers may use
an insecticide for armyworms in occasional years.
Hessian fly is a sporadic pest and increasingly common.It is a larger problem
in the southern and southeastern regions where late planting and use of fly-free
dates is not practical.It is also a problem in the Piedmont when cultural
practices support its development. Problem fields are often unrecognized.
For those with a persistent Hessian fly problem, high-risk situation, or
susceptible variety, Gaucho (imidacloprid) seed treatment or Di-Syston
(disulfuton), at planting are the best available tools. Current research
indicates Warrior may be a viable rescue treatment and provide protection from
additional oviposition if thresholds are low and timing is correct. Varietal
research has provided some strains less desired by our Biotype-L fly.
Insecticides:
Insecticides:
Cultural Control Practices:
Varietal testing and breeding for resistance to cereal leaf beetle are
currently being conducted. Recent refinement of thresholds for cereal leaf
beetle better define when pesticides are needed.
Biological Control: Biological control does not provide an immediate or complete solution to the
problem with CLB. Time is required for parasites to become established in the
field and to begin effective control of pest populations. North Carolina
chemical control recommendations are available in the North Carolina
Agricultural Chemicals Manual.
Other Issues:
Restrictions based on ability to give this commodity to people or animals as
feed or hay, limit choices of chemicals for control of these pests.The chemicals
available are not labeled across the board for all grains such as wheat, barley,
rye, triticale, oats, sorghum, or for uses such as feed versus hay.
Small grain fields need to be monitored during the season to detect any
developing problems. Growers need to familiarize themselves with weather
conditions that favor diseases to aid in determining when to scout fields or
apply crop protection chemicals. To apply disease control measures logically,
growers must know which diseases are in their fields and their severity. County
Cooperative Extension Service agents provide further information on small grain
disease identification, scouting techniques, and a list of resistant varieties
suited for each production area.
This is the most important virus disease of wheat (also oats, barley and rye)
in North Carolina. Barley yellow dwarf virus is most likely to occur after a
warm fall and mild winter that favor grass (alternate host), cereal growth, and
aphid multiplication. Symptoms are often overlooked or thought to be nutritional
problems. Leaves are discolored in shades of yellow, red, or purple, especially
from the tip to the base and from the margin to the midrib. Plants are stunted
if infected early in the fall and are progressively less stunted if infections
take place as the plant matures. Infected plants are normally found in small
areas that are usually only a few feet in diameter. The virus is transmitted by
aphids from grasses such as orchard grass, tall fescue, ryegrass, and others. It
must survive in a living host and cannot live in plant debris or the soil. The
oat-bird cherry aphid and English grain aphid are the most important in the fall
and spring respectively. Aphids overwintering on corn are believed to be an
important vector of the disease. The greenbug aphid is not a transmitter.
Controlling aphids with insecticides after infestation has not proven to be
effective against BYDV. Use of Gaucho seed treatment has been shown to be a
relatively effective preventive control for BYDV by reducing early aphid
feeding. Growers in areas with a history of BYDV avoid planting varieties that
are known to be susceptible to this disease. Oats are the most susceptible small
grain. The little available information about wheat and barley resistance by
variety is given in Table 1.
Table 1.Resistance to barley yellow dwarf virus by wheat and barley
varieties.
Wheat Varieties Very Susceptible FFR 555, AgriPro Marion, AgriPro Shelby, AgriPro Patton, Wakefield
Moderately Resistant Madison, NK Coker 9835, AgriPro Hickory, NKC 9663, Roane NKC 9663 Moderately Susceptible Boone Callao, Nomini, Pennco, Starling, Wysor
Symptoms may occur at any time during the growth of the plant and on any
portion of the plant. Lesions are round to lens shaped and are found on the
oldest leaves first. Lesions begin with a water soaked appearance, later drying
to have a yellow or red-brown color. Tissue death eventually extends beyond the
lesion; sometimes the entire leaf is killed. A diagnostic feature in older
lesions is small dark "pimplelike" spots known as pycnidia. The fungus is
dispersed by windblown rain. Wet windy weather that favors spore dispersal
increases the severity of this disease. Dry periods not only prevent infections,
but halt disease development. Rotations away from small grains for at least
three years and seed treatments, which control seedborne Septoria have been
shown to be effective disease control measures.
Chemical Controls:
Loose smut symptoms occur between heading and maturity. At first, diseased
heads are blacked and clearly visible among newly emerged green, healthy heads.
Infected heads emerge slightly earlier than normal and have their spikelets,
except for a delicate membrane, entirely transformed into a dry olive-black
spore mass. The membrane tears easily as heads emerge, and once the spores are
dispersed by wind, all that remains is the stem or rachis (stem of the head).
Infections occur only during flowering and are favored by wet weather and cool
to moderate temperatures (61 to 72 degrees F). Within one week after flowering,
the ovary and attachments become resistant. Infected seed do not appear
abnormal. The fungus that is found inside the embryo of the seed will grow
within the seedling when these seeds are planted and begin to germinate. Only
after seed heads emerge from plants, which came from infected seed are the
smutted grains seen. Therefore, infection that takes place in one year is not
seen until plants from the infected seed mature in another year.
Lesions are first noticeable as white, powdery spots on the lower leaves and
stems. As the lesions mature they become darker, sometimes salmon colored with
black spots (perithecia). If there is a heavy infestation, clouds of white
spores can be seen as you walk through the wheat. Spores are dispersed by wind.
High humidity (with or without rain) and cool temperatures (59 to 72 degrees F)
favor disease development. The disease is markedly retarded above 77 degrees F.
Some areas of a field may be sparsely populated with wheat. This may
first be noticed as a weedy area. Seedlings will be rotted or will have lesions
and be generally unthrifty. Root rots cause plants to be stunted, wilted, and/or
discolored. The roots will have an unhealthy, darkened appearance. The fungi
that cause these problems are rather common in most fields; therefore, dispersal
is not as important as with other diseases. Exceedingly wet and cool weather
favors root rot. Any conditions that retard seed germination can result in
seedling disease.
Lesions are small, circular, and vivid orange-red in color. They may occur on
stems, but are most common on the upper surface of the leaves. When heavily
infected, the whole leaf will die. Winds can carry rust spores for great
distances. Rapid development occurs between 59 to 72 degrees F when moisture is
not limiting.
Scab is seen as prematurely bleached heads or spikelets. If the rachis is
infected, everything above that point will be faded. Small dark spots
(perithecia) and superficial pink or orange fungal growth (mycelium and spores)
can be seen at the base of the spikelets. Only partly filled seed will be found
in the infected spikelets. The fungus is spread by air currents. Moist, warm (77
to 86 degrees F) weather favors scab.
Table 2. Diseases and Management Methods
Disease Management Methods
Cultural Practices: Resistant Varieties: Seed Treatments: Chemical Controls: Foliar Fungicides:
Fungicides are applied to protect the flag leaf and head from disease damage.
This may require applications as early as Feekes Growth Stage 6 (first node) or
as late as stage 10.1 or head emergence. Although fungicides are sometimes
sprayed on small grains to help control foliar diseases, net profit is increased
only if the amount of disease controlled produces more income than the treatment
costs. Some of the considerations that North Carolina growers use in determining
whether to spray fungicides are:
Disease Comments Leaf Rust* Apply fungicide only when rust covers 1 to 3% of area of upper
leaves. Powdery Mildew* Apply fungicide only when rust covers 5 to 10% of area of upper
leaves. If 25% of the indicator leaves have one or more lesions, then a
fungicide application is indicated.
Indicator leaves are: * When spraying for Powdery Mildew or Rust always apply a fungicide
that is efficacious against Septoria.
Scouting Procedures:
Beginning in mid-March, fields are scouted on a weekly basis to check for
disease occurrence. Care is taken to correctly identify the disease. The
following steps are used as a guide in developing the scouting procedure.
Disease Summary:
Successful disease management requires skillful planning and foresight since
few postplanting practices are useful. Disease management is inseparable from
plant production practices such as soil fertilization management, seedbed
preparation, and rotation. Resistant varieties and other cultural control
practices are the best means of controlling diseases. Awareness of varieties
that are currently resistant is an important part of preplant planning.
Intensive management increases the likelihood that foliar fungicides will be
beneficial. However, the use of foliar fungicides will not normally pay in North
Carolina under the prevailing economic conditions. Triadiminol (Baytan) seed
treatment is a practical way to achieve fall and early spring chemical
protection from smut and powdery mildew, as it is relatively inexpensive and
effective. The majority of growers use resistant varieties and a few growers use
some type of seed treatment.
Chemical Control: Table 4. Foliar fungicides for wheat leaf disease control in North
Carolina.
Disease Chemical (Chemical Class) Comment Mancozeb (dithio-carbamate) Minor use. Propiconazole is possible alternative. Minor use. Propiconazole is possible alternative. Mancozeb (dithio-carbamate) Minor use. Propiconazole is possible alternative. In North Carolina, weeds that most often interfere with small grains are
winter annuals, which germinate in the fall or early winter, and perennials such
as wild garlic and curly dock. Winter annuals include broadleaf weeds and annual
(Italian) ryegrass. One of the best tools for suppressing weeds in small grains
is a healthy, vigorous crop. A shallow tillage before seeding will often kill
germinating weed seeds and existing plants. For no-till, a burndown herbicide is
recommended if weeds are present in the field at planting. If weeds germinate
later, a postemergence herbicide is sometimes used.Good management practices are
used to minimize the effects of weeds in small grain production.
2,4-D Different formulations of 2,4-D are labeled for use in wheat and other winter
crops. The esters are somewhat more effective in controlling weeds than are the
amine salt or acid formulations. Since esters tend to be more soluble in oily or
organic substances, they are able to penetrate waxy leaf surfaces more quickly
and are not as easily washed from plant surfaces by rainfall. Their ability to
evaporate a little faster aids entry into leaf pores. Common ester forms include
butoxyethanol, 2-butoxyethyl, butoxypropyl, butyl, ethyl, isoctyl, and isopropyl
esters. The various esters are about equal in providing control, but the
volatile forms (ethyl, butyl, and isopropyl) are more likely to evaporate under
hot temperatures and move from the sprayed area, causing injury to nearby
susceptible plants.
At least 15 different salts are available in formulations. At least one
formulation is available as an oil soluble amine and provides somewhat better
plant entry and control than do the regular amine formulations. Rates vary
between 0.25 and 1.0 pounds active per acre. Higher rates are used only for
difficult perennial weed problems or resistant annual weeds.
Dicamba
Low rates of dicamba can injure some plants, so caution is used to prevent
drift to nearby crops. Dicamba is sold under the trade name Banvel and contains
4 pounds per gallon dicamba. It is applied alone or as a tank mix with either
2,4-D amine or ester to provide wider spectrum weed control. Tank mixtures with
high rates of 2,4-D sometimes cause some crop injury.
Diclofop
Diclofop is sold under the trade name Hoelon. It is applied pre- or
postemergence to wheat, but only postemergence to barley. Hoelon is used for
ryegrass control and control of a few other winter grasses especially when
applied at higher rates as a preemergence treatment. Hoelon cannot be applied to
oats because it causes severe injury. Thorough and uniform spray coverage of
ryegrass is necessary for good control. Rainfall is needed within seven days of
application for best preemergence control.
Symptoms on ryegrass are slow to develop and depend on how fast growth is
occurring. It is not uncommon for 10-14 days to elapse before symptoms begin
developing. Strains of ryegrass that are resistant to Hoelon are found in many
parts of the southeast. If resistant strains are observed in a field, Hoelon is
discontinued.
Prosulfuron
Prosulfuron is marketed as Peak herbicide. It is rated good to excellent for
control of wild garlic, wild mustard, wild radish, field pennycress,
shepherdspurse and cutleaf eveningprimrose. Peak is not very effective on henbit
or chickweed. It is sometimes tank-mixed with 2,4-D or dicamba to provide
broader spectrum control. It is also mixed with nitrogen solution for
application. Peak performs best when applied on days when temperatures are
expected to reach 50 degrees F or higher. Peak has a 10-month rotation
restriction for soybeans, cotton, peanut, and tobacco.
Thifensulfuron-methyl + Tribenuron-methyl
Thifensulfuron-methyl + tribenuron-methyl is marketed under the trade name
Harmony Extra. Harmony Extra is used for control of wild radish and wild garlic.
It is also used for many broadleaf weeds such as dock, thistle, chickweed,
buttercup, and wild turnip. It is applied after harsh winter temperatures have
ended and wild garlic plants are less than 12 inches tall and new crop growth is
4 to 6 inches. Several hours of dry weather are needed after application. When
liquid nitrogen is used as the carrier, early temporary yellowing or stunting of
the small grain sometimes occurs, especially if the temperature is high. It is
recommended to reduce the rate of surfactant as instructed on the label when
liquid nitrogen is used as the carrier, to avoid small grain damage. Visual
effects on weeds from Harmony Extra are not be evident for three to five weeks
after application, but weed competition is reduced quickly after spraying.
Special Considerations for No-Till Small Grains:
In a no-till system, weed control at planting is critical. In a
conventionally planted small grain crop, newly germinated weeds are destroyed
during land preparation. In no-till, winter annual weeds (chickweed, henbit, and
knawel) are up and growing at planting time. Unless controlled, they will be
very competitive with the emerging small grain for nutrients, sunlight, and
moisture during fall and early winter.
Emerged weeds are controlled by applying 1.5 pint per acre of Gramoxone Extra
after planting but before small grain emergence. A higher chemical rate is
sometimes needed for a dense weed population, cool or cold growing conditions,
or drought.
Roundup Ultra or other glyphosate formulation are also used at the rate of
0.5 to 2.0 quart per acre. The low rate is effective on winter annuals less than
2 inches tall. For taller annuals, a higher rate is recommended.Both Gramoxone
and glyphosate are used with a spray adjuvant to be effective. Adjuvant
concentration is dependent on several factors such as weed growth stage.Fan-type
nozzles are recommended with 10 to 40 gallons of water per acre. Low glyphosate
rates are more effective when applied in 3 to 10 gallons of water per acre.
When few or no weeds are present at planting, weed control measures are
postponed until after the small grain reaches the two-leaf stage. For
postemergence control of small winter annuals and wild garlic, Harmony Extra is
recommended at 0.3 to 0.4 ounces per acre. Good timing is stressed for fall weed
control. Winter annuals quickly get too large to control easily and cause
substantial yield reductions.
Early spring weed control is the same for no-till systems as for
conventional-till small grain systems. Fields are inspected to determine what
weeds are present and if a chemical weed control treatment is necessary.
Special Considerations about Herbicide Resistance:
Herbicide-resistant weeds survive and grow normally at dosages that usually
control the weed effectively. Resistance results from a change or genetic shift
within a population that impairs control in the field. An herbicide-resistant
weed may be present initially in a field in very small numbers within the weed
population (perhaps one in a billion or less). As selection pressure, from the
continued use of the same herbicide or herbicides with similar modes of action
(same herbicide group), acts on the weed population, there will be a shift in
the overall weed population from susceptible weeds to resistant weeds. This
occurs because the resistant weed population is allowed to set seed and flourish
under conditions of reduced competition due to the continued control of the
susceptible weed population.
Recommendations to avoid or delay the build up of herbicide resistance
include a rotation of herbicides with different modes of action. The use of a
good crop rotation helps make alternative herbicide selection easier. Cultural
control methods such as the use of weed-free seed and tillage are utilized to
combat herbicide resistance. Herbicides are recommended only when needed. Weeds
are tolerated in a crop if they are below levels that cause economic damage.
Growers are encouraged to keep good records of herbicide applications on a per
field basis in order to help in rotating herbicides.
If weed resistance to an herbicide is suspected, growers first check that the
problem is not a result of adverse environmental conditions, spray timing,
rates, application procedures, or a late flush of weeds. Herbicide resistance is
suspected when:
* Weed escapes occur in irregular shaped patches.
* Weeds previously controlled by a herbicide escape treatment, while other
labeled weeds are controlled.
* Grower records show repeated use of the same herbicide or group of
herbicides.
* Grower can't attribute escapes to environmental conditions or (with
postemergence products) weed emergence after application.
* The same herbicide or herbicide group failed in the same area of the field
in the previous year.
Special Considerations for Wild Garlic Control: For many years, infested wheat fields at the fully tillered stage have been
treated with 2 pints of 2,4-D per acre. Low volatile esters of 2,4-D are more
effective in controlling garlic. These, however, are not recommended for use
near susceptible crops or plants. This amount of 2,4-D does not effectively kill
wild garlic, though the production of aerial bulblets is reduced. Also, the tops
of garlic plants are sometimes bent down so that a grain combine is set high
enough to pass over them without picking up garlic bulblets. Banvel, at a rate
of 0.25 pint per acre, is sometimes added to the 2,4-D. Control has been
variable from year to year. Weather conditions and size of the wild garlic
influences the degree of control. Spraying wild garlic when 6 to 8 inches tall
seems preferable for control.
Harmony Extra provides more effective wild garlic control when wild garlic is
less than 12 inches tall with 2 to 4 inches of new growth. Harmony Extra is
applied at 0.5 ounce per acre with a non-ionic surfactant of at least 80 percent
active ingredient at 2 pints per 100 gallons of spray solution. Typical symptoms
of dying wild garlic plants (discoloration and collapse) may not be noticeable
for three to five weeks. The above rate will also control a number of common
winter annual broadleaf weeds. However, if the goal is to control only winter
annual broadleaf weeds, the rate is reduced.
Peak is also very effective against wild garlic at rates of 0.25 to 0.5
ounces per acre. Non-ionic surfactant is added to the spray solution at 1 quart
per 100 gallons of water or liquid nitrogen.
Special Considerations for Ryegrass Control:
Ryegrass is extremely competitive with wheat and barley and can greatly
reduce yields. Hoelon selectively controls annual (Italian) ryegrass. Hoelon is
applied preemergence in wheat only.
For postemergence control in wheat and certain barley varieties, Hoelon is
applied when the ryegrass is in the two to five-leaf stage. Hoelon is less
effective on ryegrass beyond the five-leaf stage and does not control broadleaf
weeds. When spraying wheat, crop oil concentrate is sometimes added to the water
carrier at 1 to 2 pints per acre. For postemergence applications in barley, only
a water carrier with no crop oil concentrate is used. Hoelon is not readily
translocated, so thorough spray coverage is recommended. Hoelon and liquid
nitrogen are not tank mixed. Hoelon may be tank mixed with Buctril (a restricted
use pesticide) for broadleaf control. However, Buctril is not effective on
several of the most common winter annual broadleaf weeds found in North Carolina
small grain fields. It is suggested that Hoelon and Harmony Extra should not be
tank mixed for application in North Carolina. Hoelon is also never tank mixed
with 2,4-D or Banvel. 2,4-D or Banvel are not used within five days of applying
Hoelon because it would reduce ryegrass control. Hoelon acts slowly. Ryegrass
appears reddish or brown and withered within two to three weeks.
Chemical Controls:
Randy Weisz Jan Spears Mike Linker Ron Heiniger Alan York John Van Duyn Steve Bambara Carl Crozier Larry D. King Robert Mikkelsen
Edited by: Stephen J. Toth, Jr., Extension Specialist-Pest Management
Information, Department of Entomology, North Carolina State University
Worker Activities
October-November: Worker on a tractor makes one pass over
the field to drill in seed.
November-December-January:Most wheat
fields are ignored. With a small percentage (less than 10%) of fields, a
worker may make a single pass to apply Hoelon for ryegrass control, or Warrior
for Hessian fly control.
February-March: Worker on a tractor
applies a broadleaf herbicide to all fields. Topdress N is applied to all
fields. Sometimes this is done as a single pass using a tank mix.
Sometimes it is done as two distinct passes.
April-May:
About 30% of wheat fields are sprayed in a single pass with an insecticide
for cereal leaf beetle. A small percentage of fields (less than 10%) get a
single pass for a fungicide application.
June: A worker
drives over the field once with a combine. Another worker drives a truck
to haul away the grain.
Insect and Mite Pests
Diseases
Common Diseases of Small Grains in North Carolina
Resistant
Barley Varieties
Moderately Resistant
Root Rots and Seedling Diseases
Scab (Fusarium blight)
Rust (leaf)
Scald
Helminthosporium leaf spot
Wheat soilborne mosaic virus
Oat soilborne mosaic virus
Poor plant color
Table 3. Fungicide thresholds for diseases of small grains in
North Carolina.
Septoria
Feekes Growth Stage 6-8: Flag 4, and Flag 5.
Feekes Growth Stage 8-10: Flag 3.
Feekes Growth Stage 10-10.51:
Flag 2.
Feekes Growth Stage 10. 52-11: Flag 1.
Septoria leaf blotch
Septoria glume bloth
Mancozeb (dithio-carbamate)
Tan spot
Helminthosporium
Mancozeb (dithio-carbamate)
Minor use. Propiconazole is possible alternative.
Weeds
Contacts
Extension Specialist
Department of Crop Science
North
Carolina State University
Box 7620
Raleigh, NC 27695-7620
Telephone:
(919) 515-5824
E-mail: Randy_Weisz@ncsu.edu
Extension Specialist
Department of Crop Science
North
Carolina State University
Box 7620
Raleigh, NC 27695-7620
Telephone:
(919) 515-4070
E-mail: Jan_Spears@ncsu.edu
Extension Specialist
Department of Crop Science
North
Carolina State University
Box 7620
Raleigh, NC 27695-7620
Telephone:
(919) 515-5644
E-mail: Mike_Linker@ncsu.edu
Extension Specialist
Department of Crop Science
North Carolina State University
Vernon James Center
207 Research
Station Road
Plymouth, NC 27962
Telephone: (252) 793-4428
E-mail: Ron_Heiniger@ncsu.edu
Extension Specialist
Department of Crop Science
North
Carolina State University
Box 7620
Raleigh, NC 27695-7620
Telephone:
(919) 515-5643
E-mail: Alan_York@ncsu.edu
Entomology:
Extension Specialist
Department of Entomology
North
Carolina State University
Vernon James Center
207 Research Station Road
Plymouth, NC 27962
Telephone: (252) 793-4428
E-mail: john_vanduyn@ncsu.edu
Extension Specialist
Department of Entomology
North
Carolina State University
Box 7613
Raleigh, NC 27695-7613
Telephone:
(919) 515-1661
E-mail: Steve_Bambara@ncsu.edu
Soil Science:
Extension Specialist
Department of Soil Science
North Carolina State University
Vernon James Center
207 Research
Station Road
Plymouth, NC 27962
Telephone: (252) 793-4428
E-mail: Carl_Crozier@ncsu.edu
Emeritus Professor
Department of Soil Science
North
Carolina State University
Box 7619
Raleigh, NC 27695-7619
E-mail: Larry_King@ncsu.edu
Adjunct Professor
Department of Soil Science
North Carolina State University
Box 7619
Raleigh, NC 27695-7619
Telephone: (530) 758-4237
E-mail: RMikkelsen@ppi-far.org
References
On-Line Resources
Authors: Stephen B. Bambara and Randall Weisz