Browsing by Author "Kuhar, Thomas P."

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    2014 Commercial Vegetable Production Recommendations
    Reiter, Mark S.; Rideout, Steven L.; Kuhar, Thomas P.; Wilson, Henry P.; Parkhurst, James A.; Straw, Allen; Samtani, Jayesh B.; Gu, Ganyu; Mullins, Chris; Hines, Thomas E.; Waldenmaier, Christine M.; Doughty, Hélène; Mason, John E.; Freeman, Josh H. (Virginia Cooperative Extension, 2014-02-19)
    New varieties and strains of vegetables are constantly being developed throughout the world and it is impossible to list and describe all of them, only those that are available and are adapted to the mid-Atlantic region are listed in this publication. The ultimate value of a variety for a particular purpose is determined by the grower: performance under his or her management adaptation to specific environmental conditions, and having desired horticultural characteristics.
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    2016 Mid-Atlantic Commercial Vegetable Production Recommendations
    Wyenandt, Andy (Virginia Cooperative Extension, 2016-01-29)
    Provides the commercial vegetable grower with information on variety, pesticides, equipment, irrigation, fertilizer, and cultural practices in order to aid managerial decisions.
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    2020 Virginia Tech Eastern Shore AREC Virtual Research Field Day
    Reiter, Mark S.; Deitch, Ursula; Pittman, Theresa; Flessner, Michael; Rideout, Steven L.; Zhang, Bo; Vallotton, Amber; Thomason, Wade E.; Wolters, Bethany; Templeton, Jenny; Lawrence, Cris; Strawn, Laura K.; Neill, Clinton L.; Sutton, Kemper; Britt, Kadie; Boyle, Sean; Pagini, Mika; Kuhar, Thomas P. (Virginia Cooperative Extension, 2020-08-18)
    Eastern Shore Agricultural Research and Extension Center Virtual Research Field day includes various presentations and publications of the authors’ above, which are each linked in the body of the publication
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    2020-2021 Mid-Atlantic Commercial Vegetable Recommendations
    (Virginia Cooperative Extension, 2020)
    Discusses commercially grown vegetables, their growth and which pesticides to use on which crops.
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    2021 Southeastern U.S. Vegetable Crop Handbook
    Kuhar, Thomas P.; Rideout, Steven L.; Reiter, Mark S. (Virginia Cooperative Extension, 2021-01-07)
    This handbook represents a joint effort among Extension specialists and researchers from 12 land-grant universities in the U.S. who work in the area of vegetable production. These specialists and researchers represent a wide array of disciplines: agricultural engineering, entomology, olericulture (vegetable production), plant pathology, postharvest physiology, soil science, and weed science.
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    2021 Virtual Eastern Shore Agricultural Conference and Trade Show
    Pittman, Theresa; Deitch, Ursula T.; Reiter, Mark S.; Singh, Vijay; Mason, John; Duerksen, Keren; Haymaker, Joseph; Doughty, Helene; Holshouser, David Lee, 1963-; Langston, David B.; Flessner, Michael; Rideout, Steven L.; Thomason, Wade E.; McCullough, Chris T.; Sutton, Kemper L.; Bekelja, Kyle; Kuhar, Thomas P.; Richardson, Bruce; Harper, Robert; Richardson, Brett; Shockley, Bill (Virginia Cooperative Extension, 2021-03-12)
    Join us for the 2021 virtual Eastern Shore Agricultural Conference and Trade Show! Hear updates and continuing education presentations that are pertinent to Eastern Shore of Virginia growers.
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    2022-2023 Mid-Atlantic Commercial Vegetable Production Recommendations
    Reiter, Mark S.; Samtani, Jayesh; Torres Quezada, Emmanuel; Singh, Vijay; Doughty, H.; Kuhar, Thomas P.; Sutton, Kemper; Wilson, James; Langston, David B.; Rideout, Steven; Parkhurst, James; Strawn, Laura K. (Virginia Cooperative Extension, 2022-11-30)
    This copy of the 2022/2023 Mid-Atlantic Commercial Vegetable Production Recommendations replaces all previous editions of the Commercial Vegetable Production Recommendations published individually for Delaware, Maryland, New Jersey, Pennsylvania, Virginia, and West Virginia. Information presented in this publication is based on research results from the University of Delaware, the University of Maryland, Rutgers - The State University of New Jersey, The Pennsylvania State University, Virginia Polytechnic Institute and State University, West Virginia University, and the U.S. Department of Agriculture, combined with industry and grower knowledge and experience. This publication will be revised biennially. In January 2023, a Critical Update with important updates for this publication will be communicated through local Extension Agents and Vegetable Specialists. The editors welcome constructive criticism and suggestions from growers and industry personnel who may wish to help improve future editions of this publication. These recommendations are intended for the commercial vegetable grower who has to make numerous managerial decisions. Although the proper choices of variety, pesticides, equipment, irrigation, fertilizer, and cultural practices are the individual vegetable grower’s responsibility, it is intended that these recommendations will facilitate decision-making. Recommended planting dates will vary across the six-state region. Local weather conditions, grower experience, and variety may facilitate successful harvest on crops planted outside the planting dates listed in this guide. This can be evaluated in consultation with the local agents and state specialists. Government agencies and other organizations administrating crop insurance programs or other support programs should contact local Extension agents and/or vegetable specialists for guidance. Not to be used by home gardeners.
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    Abundance and Species Diversity of Thrips (Thysanoptera: Thripidae) in Cotton, Soybean, and Peanut in Southeast Virginia, and Evaluation of Cyantraniliprole for Thrips Management
    Samler, Jessica Anne (Virginia Tech, 2012-04-24)
    Thrips are major agricultural pests throughout much of the United States. More information is needed about sampling methods, management practices, and insecticide susceptibility to help better control this pest. A two year survey was conducted to determine the species present in southeast Virginia and the population characteristics of those species. Thrips were monitored using yellow sticky traps. Tobacco thrips, Frankliniella fusca, were the most abundant species. In general thrips populations began to build up beginning in April, peaked in August, and then started to decline. Differences in this trend were observed between species. A study was conducted in seedling soybean to evaluate the within-plant location of thrips, whether a plant subsample could be used for thrips monitoring, and to determine the thrips species complex present. Soybean thrips, Neohydatothrips variabilis, were the most prominent species present. The greatest density of thrips larvae was located in the terminal bud of the seedling and suggests that immature thrips aggregate. Neither of the proposed subsamples of plant material explained the variability in immature thrips numbers and at this time we recommend whole-plant sampling for obtaining the most accurate estimate of thrips populations in seedling soybean. Tobacco thrips, F. fusca, as well as a complex of other thrips species attack cotton and peanut seedlings and can cause significant yield loss to these crops in the mid-Atlantic U.S. Experiments were conducted in these two crops to assess the efficacy of a novel diamide insecticide cyantraniliprole applied as a liquid in-furrow at planting and post-plant emergence broadcast spray treatment to control thrips. In both cropping systems cyantraniliprole significantly reduced the number of immature thrips and reduced thrips feeding injury to the plants. In several instances cyantraniliprole treatments resulted in increased yield as compared to the non-insecticide treated control and yields which were statistically similar to those obtained with standard thrips control insecticides. Laboratory bioassays were conducted to evaluate the toxicity (LC50 values) of cyantraniliprole and two conventional insecticides against F. fusca adults. Results of these assays were inconclusive. At times F. fusca adults were susceptible to the insecticides, but the results could not be replicated consistently.
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    The Alydidae (Broad-Headed Bugs) of Virginia and Their Pest Management in Edamame
    Wilczek, Daniel Kaye (Virginia Tech, 2022-06-08)
    Edamame, also known as edible soybean, is a crop with growing demand in the United States. Currently much of the edamame consumed in the United States is imported, but it has potential to be grown domestically, in Virginia and other mid-Atlantic states. With the introduction of a new crop, however, comes new challenges, such as novel pests. The broad-headed bugs (Hemiptera: Alydidae), a relatively insignificant pest of conventional soybean, have been observed in high numbers on edamame in Virginia. Their piercing-sucking feeding may produce dark marks on edamame beans that could result in economic losses. However, little research has been conducted on the pest status or management of these bugs in edamame. This study aims to determine their pest potential to edamame by investigating their distribution throughout the state, damage to the crop, and avenues for chemical control. An important element in determining the pest potential of an insect is its distribution throughout an area. The distribution of broad-headed bugs in Virginia was last thoroughly investigated in 1975, and the research has scarcely been updated since. With advances in technology, however, it is now possible to crowd-source data from citizen scientists to supplement museum and field collection data. The first portion of this study explores the species of broad-headed bugs present in Virginia, and their distribution throughout the state. This was achieved using museum specimens, field-collected specimens, and photographs from the social network iNaturalist. By manually checking iNaturalist identifications of broad-headed bugs using a key, I was able to determine that iNaturalist is 96% accurate at identifying North American broad-headed bugs to species. Through the combination of museum, field, and iNaturalist data, I also found evidence of two species of broad-headed bug at elevations never before seen in Virginia, the first broad-headed bug ever found on the Eastern Shore of Virginia, as well as the first documented sighting of Hyalymenus tarsatus Fabricus in Virginia. The level of injury that broad-headed bugs cause to edamame is presently unknown. The second portion of this study compares the density-damage relationship of broad-headed bugs on edamame to that of the brown marmorated stink bug (Halyomorpha halys Stahl), a known pest of edamame. Through a cage study conducted in Whitethorne, Virginia, I found that broad-headed bugs cause significant damage to edamame at densities of 10 insects per plant, but still less damage than that of brown marmorated stink bugs. Currently, no economic injury thresholds exist for broad-headed bugs, or brown marmorated stink bugs on edamame. Determining the density-damage relationship of these insects on edamame may contribute to the creation of these thresholds in the future. The third portion of this study is the first attempt at evaluating chemical control of the broad-headed bugs on edamame. I performed a bioassay evaluation of four commercial selective insecticides including the following: flupyradifurone and sulfoxaflor, both with a mode of action similar to neonicotinoids, but with reduced non-target effects; the diamide cyclaniliprole, and a novel venom-like peptide insecticide, GS-omega/kappa-Hxtx-Hv1a. Each of the insecticides caused significant mortality of Alydus eurinus (Say) adults. This thesis serves as a starting point in evaluating the potential threat of broad-headed bugs to Virginia's edamame production.
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    Ambient moisture causes methomyl residues on corn plants to rapidly lose toxicity to the pest slug, Arion subfuscus, Muller (Gastropoda, Stylommatophora)
    Nottingham, Louis B.; Kuhar, Thomas P. (Elsevier, 2021-09-01)
    The carbamate insecticide methomyl is sometimes used to control slugs in field corn and soybean by foliar applications, but control outcomes in research trials and commercial operations have been mixed. In this study, laboratory bioassays were conducted on dusky slug, Arion subfuscus Müller, a common pest of corn and soybean in the Mid-Atlantic United States, to evaluate residual toxicity of Lannate LV (methomyl) at low and high concentrations corresponding to label recommended field rates, and if toxicity may be affected by ambient moisture or repellency to treated plants. Without wetting events, methomyl residues on corn plants caused 90–100% mortality of A. subfuscus for two days and 70–90% mortality for six days. When corn plants were briefly misted with ca. 0.3 cm of water 6 h after methomyl application, mortality was 36% 12 h after treatment, and 0 to 5% 24 h after treatment for both low and high rates. Repellency of A. subfuscus to corn plants treated with the high rate of methomyl was narrowly significant (P = 0.04) and low rate was not significant. These results suggest that high ambient moisture needed to elicit slug activity in the field also abates toxicity of methomyl residues, explaining why field control is usually poor despite high mortality in the lab.
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    Arthropod Pest Management Research on Vegetables in Virginia - 2010
    Kuhar, Thomas P.; Schultz, Peter B.; Doughty, Hélène; Jenrette, James (Virginia Cooperative Extension, 2011-02-22)
    Describes arthropod pest management research on vegetable crops including evaluation of federally-labelled and experimental insecticides.
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    Arthropod Pest Management Research on Vegetables in Virginia - 2011
    Kuhar, Thomas P.; Schultz, Peter B.; Doughty, Hélène; Kamminga, Katherine; Jenrette, James (Virginia Cooperative Extension, 2012-02-01)
    Describes arthropod pest management research on vegetable crops including evaluation of federally-labelled and experimental insecticides.
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    Arthropod Pest Management Research on Vegetables in Virginia--2013
    Kuhar, Thomas P.; Schultz, Peter B.; Doughty, Hélène; Jenrette, James (Virginia Cooperative Extension, 2014)
    This booklet contains arthropod pest management research conducted on vegetable crops in Virginia in 2013.
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    Asparagus Beetles
    Day, Eric R.; Kuhar, Thomas P. (Virginia Cooperative Extension, 2017-09-27)
    Describes two species of asparagus beetle Crioceris asparagi and Crioceris duodecimpunctata, their life cycles, damage to asparagus plants, and methods for control.
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    Asparagus Beetles on Asparagus
    Kuhar, Thomas P.; Day, Eric R. (Virginia Cooperative Extension, 2009-07-29)
    Describes life history of Crioceris asparagi and Crioceris duodecimpunctata and damage to asparagus. Also notes methods for controlling these crop pests.
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    Asparagus Beetles: Coleoptera: Chrysomelidae, Crioceris asparagi (L.) and Crioceris duodecimpunctata (L.)
    Day, Eric R.; Kuhar, Thomas P. (Virginia Cooperative Extension, 2009-05-01)
    Describes life history of Crioceris asparagi and Crioceris duodecimpunctata and damage to asparagus. Also notes methods for controlling these crop pests.
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    Bean leaf beetle (Coleoptera: Chrysomelidae) preference for two Phaseolus beans over soybean
    Shrader, Meredith Edana; Kuhar, Thomas P.; Schultz, Peter B.; Pfeiffer, Douglas G.; Kamminga, Katherine (2014)
    In the eastern and central U.S., bean leaf beetle, Cerotoma trifurcata (Förster) (Coleoptera: Chrysomelidae), is a pest of legume crops, on which adults chew holes in leaves, can destroy seedlings, and can injure pods (Smelser and Pedigo 1992a, J. Econ. Entomol. 85: 2408 - 2412; Smelser and Pedigo 1992b, J. Econ. Entomol. 85: 2399 - 2403; Koch et al. 2005, Crop Prot. 24: 734 - 742). The beetle is also a primary vector of bean pod mottle virus, which can further reduce yield and seed quality in soybeans (Giesler et al. 2002, Plant Dis. 86: 1280 - 1289). On the Delmarva Peninsula, snap beans (Phaseolus vulgaris L.), lima beans (Phaseolus lunatus L.), and soybeans (Glycine max (L.) Merr.), are each important crops, and relatively high populations of C. trifurcata occur. To better understand the potential intercrop movement of the beetle and its implications for pest management, we conducted beetle host plant preference experiments...
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    Bean Leaf Beetle Biology and Management in Snap Beans
    Cassell, Meredith E.; Kuhar, Thomas P. (Virginia Cooperative Extension, 2005-09-01)
    Describes life history of bean leaf beetles, damage to bean plants, and methods of biological and chemical control.
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    Bean Leaf Beetle: Impact of Leaf Feeding Injury on Snap Beans, Host Plant Choice and Role as a Vector of Bean Pod Mottle Virus in Virginia
    Cassell, Meredith Edana (Virginia Tech, 2011-04-12)
    The bean leaf beetle (BLB), Cerotoma trifurcata (Forster) (Coleoptera: Chrysomelidae), is a pest of commercially produced legumes in eastern Virginia. Field cage and manual-defoliation studies were conducted in Virginia to determine an economic impact of BLB. In the manual-defoliation study, snap bean plants had significant yield loss when > 25% of leaf area was removed. In the field cage experiments, I was unable to establish beetle densities per plant to impact yield. Host plant selection by BLB was done in laboratory and field studies with snap bean, lima bean, and soybeans. Laboratory studies showed that BLB preferred snap bean and lima bean over soybean. Field studies did not showed no preference. A survey was conducted on the Eastern Shore of Virginia determine the epicenter of BPMV. Soybean leaves and beetles were collected and assessed for BPMV by ELISA or TBIA. Beetles at the ESAREC were BPMV-positive upon emergence from overwintering sites, but the virus load was low when tested by ELISA. This suggests acquisition of virus from a source other than infected cultivated legumes. To find the potential inoculum sources of BPMV in eastern Virginia, leguminous weeds and perennial weeds were tested for BPMV. Four weed species gave BPMV-positive tissue blots including: Oxalis stricta, Rumex acetosella, Trifolium pretense, and Trifolium repens. Insecticidal seed treatment of thiamethoxam on soybean seeds was evaluated to test the efficacy. Leaf area eaten and beetle mortality was measured. The thiamethoxam seed treatment protected soybean seedlings from beetle feeding through the V2 stage of growth.
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    Bean Pod Mottle Virus in Virginia Soybeans
    Cassell, Meredith E.; Tolin, Sue A.; Kuhar, Thomas P.; Schultz, Peter B. (Virginia Cooperative Extension, 2009-10-09)
    Describes disease cycle of Bean Pod Mottle Virus in soybeans. Also describes symptoms, possible sources of this disease, and management methods.