Alfalfa, also known as lucerne, is an important forage crop grown throughout the world However, alfalfa plants are susceptible to damage from insect pests like alfalfa weevil, aphids, armyworms, and alfalfa stem borers Borers are moth larvae that bore into the stem of plants and disrupt nutrient and water transport. Severe borer infestations can kill alfalfa plants. If you notice borer damage in your alfalfa field, timely control measures are essential to save the crop. This article discusses various methods for effective borer control in alfalfa.
Identifying Borer Infestation
The first step is to scout your field and accurately identify the pest, Look for these signs of borer activity
- Holes in stems – Larvae bore into stems and create entry/exit holes
- Frass – Sawdust-like excrement pushed out through holes
- Wilting and dying stems – Girdling of stems disrupts water flow
- Swollen nodes – Chewed up tissues swell at nodes
- Lodging – Damaged stems break and plants lodge or fall over
There are several species of stem borers that infest alfalfa including the alfalfa stem borer, grape cane borer, celery borer, and the European corn borer. Proper identification will help select targeted management options. Contact local extension agents if you need help with pest ID.
Cultural Control Practices
Certain agronomic practices can help reduce borer problems in alfalfa fields:
- Cut early – Harvest alfalfa prior to full bloom stage to avoid infestations.
- Maintain vigor – Fertilize and irrigate to keep plants healthy and less vulnerable to borers.
- Reduce stresses – Minimize compaction, drainage issues, and weed pressure.
- Use tolerant varieties – Some alfalfa varieties have antibiosis resistance against specific borers.
- Clean up crop residue – Eliminate stalks and stubble that serve as overwintering sites.
- Timely harvesting – Cut alfalfa as soon as it reaches the bud stage after the first killing frost. This removes food sources for larval development.
- Rotate crops – Do not grow alfalfa in the same field year after year. A 2-3 year rotation helps break borer cycles.
While cultural practices alone may not eliminate borers, they create less favorable conditions for infestations to become severe.
Chemical Control Measures
Insecticide application is an effective remedy when borers reach damaging thresholds. Foliar sprays and systemic treatments can both be used:
Foliar Sprays
- Apply broad-spectrum insecticides like permethrin, zeta-cypermethrin or lambda-cyhalothrin. Spray young larvae before they bore into stems.
- Target small larvae in early spring or after each alfalfa cutting. Large larvae deep inside stems are harder to control.
- Spray insecticides in evenings when pollinators are less active to minimize bee mortality.
- Follow label directions carefully for dosage, timing, pre-harvest intervals, worker protection standards and grazing restrictions.
Systemic Insecticides
- Seed treatments – Coating alfalfa seeds with systemic insecticides like thiamethoxam controls larvae and other early season pests.
- In-furrow sprays – Applying insecticides like chlorpyrifos and tefluthrin in planting furrows also protects young seedlings.
- Foliar sprays – Newer insecticides like chlorantraniliprole and cyantraniliprole are absorbed into plant tissues and kill larvae internally. They provide longer control than conventional contact insecticides.
Both foliar sprays and systemic insecticides are effective against larval stages. But foliar sprays also control adult moths and reduce egg laying if timed right. Consult local agronomists and follow product labels when using insecticides. Proper stewardship is vital to avoid insect resistance, environmental contamination and livestock toxicity issues.
Biological Control Options
Natural enemies can be used as part of an IPM program for long term, sustainable borer management. Some beneficial options include:
Parasitic wasps
- Tiny wasps like Bathyplectes curculionis parasitize borer larvae. The developing wasp eventually kills the feeding larva.
- Turnover of generations is very fast allowing rapid buildup of wasp populations.
- Release parasitized borer larvae from insectaries onto infested alfalfa fields. The adult wasps will emerge and attack more borers.
Predatory insects
General predators like lady beetles, minute pirate bugs, damsel bugs, and lacewing larvae feed on borer eggs and small larvae. Avoid broad spectrum insecticide sprays which would kill populations of these beneficial insects.
Entomopathogenic nematodes
- Microscopic roundworms like Steinernema carpocapsae or Heterorhabditis bacteriophora enter and kill borer larvae.
- Apply high numbers of infective juveniles onto fields through irrigation. Active larvae get infected within a few days.
- Works best before larvae bore deep into stems. Frequent nematode releases may be required for ongoing control.
Entomopathogenic fungi
- Fungal pathogens like Beauveria bassiana infect and kill larvae through cuticle penetration.
- Can be sprayed onto foliage and stems. Persist in fields after application.
- Field trials show reasonable borer control, often enhancing effects of Bt-based insecticides.
When using biologicals, make releases before infestation reaches high levels for best results. Consult extension specialists for specific product selection, timing and application guidelines.
Integrated Pest Management
An IPM approach using multiple tactics is recommended for long term management of alfalfa stem borers. Some key IPM practices include:
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Monitor fields weekly and identify pests. Know when larvae first appear.
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Establish economic thresholds and only treat when needed. For alfalfa stem borer, a threshold of 25-50% infested stems justifies insecticide application.
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Enhance biological control by avoiding broad spectrum pesticides which kill beneficial insects and nematodes. Release parasite wasps or nematodes.
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Rotate between insecticide classes and modes of action to minimize resistance.
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Combine strategies like early cutting, variety resistance, insecticides, and biological control for greater impact.
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After treatment, continue monitoring to check control effectiveness. Retreat only if pests recover.
Implementing IPM requires more intensive management effort compared to routine insecticide applications. But the combined use of multiple tactics provides very effective and sustainable borer control on alfalfa with minimal environmental impact. The small extra investment of time and effort is well worth protecting yield and quality of this valuable forage crop.
Alfalfa stem borers can certainly cause considerable headaches for growers. But by identifying the specific pest, scouting carefully, and using well-timed control measures, their damage can be avoided. Cultural practices, insecticides, biologicals and an IPM approach together can keep borers from becoming a limiting factor in alfalfa production. Paying attention to early warning signs and implementing management strategies promptly is key to protecting your alfalfa crop.
Use low impact pesticides
Choose insecticides that are highly selective to a specific type of insect and so have low toxicity for others (signal word of Caution on the label or EPA Reduced Risk product). Other characteristics of low impact pesticides are those that break down rapidly after application and therefore have minimal impact on pollinators and natural enemies. However, using these products requires some knowledge about their relative toxicity to beneficial insects and their potential to cause leaf or flower injury (phytotoxicity). The following types of products have a minimal impact on beneficial insects.
Insecticidal soaps are applied as a foliar application (sprayed on plant leaves) and are effective on a wide range of plant pests when the soap spray comes into contact with the pest. Most commercially available insecticidal soaps are made of potassium salts of fatty acids and kill by disrupting the structure and permeability of insect cell membranes. Insecticidal soaps are most effective on soft-bodied insects such as aphids, adelgids, lace bugs, leafhoppers, mealybugs, thrips, sawfly larvae, spider mites and whiteflies. They are not effective on pests as a residue on the plant surface, and therefore are not toxic to pollinators after the spray dries. They can be safely used at any time to control pests on plants that are not attractive to pollinators. However, on pollinator-attractive plants, spray at dawn or dusk when pollinators are not present.
Generally, concentrations of insecticidal soaps exceeding 3% may cause some leaf or flower injury, and concentrations as low as 1.5% may injure sensitive plants. Read the product label for a list of sensitive plants and avoid spraying those. If uncertain of a plant’s sensitivity, spray a few leaves or flowers first and wait at least three days to watch for symptoms of spray injury, which include yellow, black or brown spots, brown (necrotic) edges on leaf and petal tips, scorch or discoloration. Some landscape plants known to be sensitive to insecticidal soap are horse chestnut, mountain ash, Japanese maple, sweet gum, jade plant, lantana, gardenia, bleeding heart, sweetpeas, crown-of-thorns and some cultivars of azaleas, begonias, chrysanthemum, fuchsias and impatiens.
It is best to purchase a commercial product formulated for use on plants rather than prepare your own spray from dish-washing detergents or other household cleaners because homemade recipes may be more toxic to plants. Most such products are detergents rather than true soaps, which can damage your plants. Only use products that are specifically formulated and labeled for use as insecticide. For more information on using insecticidal soaps, see Miller (1989), Gill and Raupp (1990) and Pundt (2004) in the reference section of this publication. Many insecticidal soap products are listed by the Organic Materials Review Institute (OMRI) at www.omri.org.
Horticultural oil is a term for the various oils used for pest control on plants. Most horticultural oils are lightweight and petroleum-based, but some are made from grains, vegetables or neem tree seeds. Like insecticidal soap, horticultural oils work best when the spray comes in contact with the pest. Once the oil spray dries, it does not have much effect and becomes safe for pollinators and other beneficial insects. Horticultural oil can be safely used at any time to control pests on plants that are not attractive to pollinators. However, on pollinator-attractive plants, spray at dawn or dusk when pollinators are not present.
Horticultural oils give excellent control of armored scales, such as Euonymus scale and oystershell scale, and can also be used for aphids, whiteflies, spider mites, true bugs, caterpillar and sawfly larvae and more. The recommended concentration of horticultural oils for pest control is usually 2%. However, even at 2%, some plants are sensitive to oils, including Japanese maple, red maple, hickory, black walnut, plume and smoketree (Cotinus coggygria). Plants reported as somewhat sensitive are Colorado blue spruce, redbud, juniper, cedar, cryptomeria and Douglas fir. Applying oils during high humidity or high temperatures may have a toxic effect on plant growth. Plant injury symptoms following an application of horticultural oil are discoloration, yellowing, leaf or flower browning (necrosis), black spots and terminal or branch dieback. It is best to spray a few plants first and observe them for three days for these phytotoxicity symptoms. Many horticultural oil products are listed by the OMRI.
Several pesticides sold are derived from naturally occurring pathogens such as bacteria or fungi. These microbial or bio-pesticides vary in their toxicity to bees, butterflies and other beneficial insects. Some bioinsecticides, such as those derived from the fungus Beauvaria bassiana, are toxic to bees and should not be used where pollinators are present. Other bioinsecticides may have low impact on pollinators due to their low toxicity or short residual, which allows them to be applied in the evening or at dawn when bees are inactive.
Considerations for using certain biopesticides
The following active ingredients are found in products that have minimal impact on bees and other beneficial insects.
Products containing B.t. are made from a naturally-occurring soil bacterium. Many different B.t. products are available for landscape professionals and homeowners. Different strains of B.t. target specific pest groups, making them selective pesticides. For example, spores and crystals of Bacillus thuringiensis var. kurstaki (B.t.k.) are highly toxic when ingested by butterfly and moth larvae (caterpillars). The crystals containing the toxin dissolve only at an extremely high pH found in the caterpillar’s gut. B.t.k. is not toxic to bees. However, avoid spraying or allowing spray to drift onto favored food plants of caterpillars such as milkweed, the sole food source for monarch butterfly caterpillars.
Another strain of B.t., B.t. galleriae (B.t.g.), targets several species of beetles in the adult and larval stages including scarab beetles (e.g., Japanese beetle), flat headed beetles (e.g., emerald ash borer), weevils and leaf beetles. B.t.g. is not toxic to bees or butterflies, but applications should be avoided where predatory beetles are active. B.t. galleriae is now available at garden centers and recent testing indicates that it will control Japanese beetle adults for two weeks after it is sprayed. It will not harm pollinators, but it is toxic to monarch caterpillars.
While a B.t. strain works well for its target pest, it also breaks down quickly in sunlight, becoming ineffective after a few days. This makes B.t. very safe for pollinators, predatory insects and mammals. B.t. can be sprayed even when bees or butterflies are present. Many B.t. products are OMRI listed.
The fungus Metarhizium anisopliae is found naturally in soils and infects and kills insects. Commercially available products of M. anisopliae (e.g., Met52) target thrips, weevils, whiteflies and mites on ornamentals, and ticks in turf. Once the product is sprayed on the foliage or drenched in the soil, the spores attach to the surface of the insect, germinate and penetrate the insect, multiply and kill it. M. anisopliae does not detrimentally impact honey bees and is being studied as a bio-insecticide of varroa mites, a pest of honey bees.
This naturally occurring bacterium is used in a fermentation process that produces a product with insecticidal properties (e.g., Grandevo PTO). It is a broad spectrum bio-insecticide/miticide that controls or suppresses insect and mite pests on ornamentals and turf. It has multiple modes of action including oral toxicity (stomach poison), repellency and reduced reproduction. This product is applied as a foliar application and targets numerous caterpillar species in addition to aphids, whiteflies, thrips, psyllids, lace bugs, chinch bugs, mites and certain beetles. It suppresses a broad number of caterpillar species and should not be sprayed or allowed to drift in known habitats for threatened or endangered species of caterpillars and butterflies, such as fields with milkweed where monarch butterfly caterpillars feed. This product may repel bees for up to six days, so time applications to avoid disrupting pollination. Grandevo PTO (active ingredient C. subtsugae) is an OMRI listed product.
Azadirachtin is the active ingredient extracted from seeds of the tropical neem tree. Bio-insecticides with azadirachtin act as an insect growth regulator (IGR) in addition to being an anti-feedant and repellant to insects. It is effective at controlling insect immature stages and is broadly labeled for adelgids; aphids; caterpillars such as budworms, tent caterpillars and webworms; beetles such as Japanese beetles, emerald ash borers, weevils and elm leaf beetles; leafhoppers; leafminers; mealybugs; psyllids; sawflies; scales; thrips; and whiteflies. Azadirachtin must be ingested to be toxic and, when applied as a foliar spray, has short residual activity, making it unlikely bees and other pollinators will be affected (no longer toxic after about two hours for bees). Direct contact has shown no effect on worker honey bees. Azadirachtin products can be safely used at any time to control pests on plants that are not attractive to pollinators. However, on pollinator-attractive plants, spray during late evening, night or early morning when pollinators are not present to minimize contact with adult bees that could potentially bring azadirachtin back to the nest where larvae are present. Many azadirachtin products are OMRI listed.
Spinosad is derived from a soil bacterium and affects the nervous system of insects and mites. It has contact activity, but is even more active when ingested. Several products containing spinosad are labeled for ornamental (e.g., Conserve) and agricultural uses to control a broad spectrum of pests including caterpillars, sawfly larvae, leaf beetle adults and larvae, thrips, leafminer and gall-making flies and emerald ash borer beetles. Spinosad is highly toxic to bees. However, toxicity is greatly reduced once the product has dried on the foliage, within three hours to one day depending on the product. Therefore, avoid use if bees are active, and if applications are needed, apply in the evening when bees are not active and product has time to dry. This product suppresses a broad number of caterpillar species and should not be sprayed or allowed to drift in known habitats for threatened or endangered species of caterpillars and butterflies. Some spinosad products are OMRI-listed and on the EPA Reduced Risk list.
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FAQ
What is the best remedy against borers?
How do you get rid of borers naturally?
What do you spray on alfalfa for bugs?
Pest
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Active Ingredient(s)
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Trade Name(s)
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Alfalfa Weevil Larva
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alpha-cypermethrin*
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Fastac
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Alfalfa Weevil Larva
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beta-cyfluthrin*
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Alfalfa Weevil Larva
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cyfluthrin*
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Alfalfa Weevil Larva
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gamma-cyhalothrin*
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When to spray for borers?