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Factors Influencing Adoption of Integrated Pest Management in Northeast Greenhouse and Nursery Production

Published online by Cambridge University Press:  15 September 2016

Jie Li ,
Miguel I. Gómez ,
Bradley J. Rickard  and
Margaret Skinner
Jie Li
Affiliation:
Dyson School of Applied Economics and Management at Cornell University
Miguel I. Gómez*
Affiliation:
Dyson School of Applied Economics and Management at Cornell University
Bradley J. Rickard
Affiliation:
Dyson School of Applied Economics and Management at Cornell University
Margaret Skinner
Affiliation:
Entomology Research Laboratory at University of Vermont
*
Corresponding Author: Charles H. Dyson School of Applied Economics and Management, 321 Warren Hall, Cornell University, Ithaca, NY 14853, Phone 607.255.8159, Email mig7@cornell.edu.
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Abstract

We collected surveys from 94 greenhouse and nursery growers in three northeastern states to examine factors influencing integrated pest management (IPM] adoption. We constructed three alternative dependent variables describing the extent of IPM adoption and employed discrete choice models to identify factors that affect adoption. We find that operations with more full-time workers are more likely to adopt IPM. Additionally, greenhouse/nursery growers that rank pests as a serious problem are likely to use a wider array of IPM practices. The reliability of IPM practices is critical for adoption. Our analysis highlights differences between self-reported and objective IPM adoption measures.

Keywords

greenhouse and nursery productionintegrated pest managementnortheast United Statestechnology adoption
Type
Contributed Papers
Information
Agricultural and Resource Economics Review , Volume 42 , Issue 2 , August 2013 , pp. 310 - 324
Copyright
Copyright © 2013 Northeastern Agricultural and Resource Economics Association 

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References

Agricultural Research Service. 1998. 1998 Census of Horticultural Specialties. U.S. Department of Agriculture, Washington, D.C. Available at www.agcensus.usda.gov/Publications/1997/Horticulture_Specialties/index.asp (accessed August 2010).Google Scholar
Agricultural Research Service. 2009. 2009 Census of Horticultural Specialties. U.S. Department of Agriculture, Washington, D.C. Available at www.agcensus.usda.gov/Publications/2007/Online_Highlights/Census_of_Horticulture/index.asp (accessed August 2010).Google Scholar
Alston, D.G. 2011. “The Integrated Pest Management Concept.Utah Pests Fact Sheet. Utah State University Cooperative Extension, Logan, UT. Available at http://extension.usu.edu/htm/publications/file=6182 (accessed August 2011).Google Scholar
Alston, D.G., and Reding, M.E. 1998. “Factors Influencing Adoption and Educational Outreach of Integrated Pest Management.Journal of Extension 36(3): Feature Articles. Available at www.joe.org/joe/1998june/a3.php (accessed January 2011).Google Scholar
Bentley, W.J. 2009. “The Integrated Control Concept and Its Relevance to Current Integrated Pest Management in California Fresh Market Grapes.Pest Management Science 65(12): 12981304.CrossRefGoogle ScholarPubMed
Brewer, M.J., Elworth, L.E., Landis, J.N., and Hoard, R.J. 2004. “The Case and Opportunity for Public-Supported Financial Incentives to Implement Integrated Pest Management.Journal of Economic Entomology 97(6): 17821789.Google Scholar
Burkness, E.C., and Hutchison, W.D. 2008. “Implementing Reduced-Risk Integrated Pest Management in Fresh-Market Cabbage: Improved Net Returns via Scouting and Timing of Effective Control.Journal of Economic Entomology 101(2): 461471.Google Scholar
Castle, S., and Naranjo, S.E. 2009. “Sampling Plans, Selective Insecticides, and Sustainability: The Case for IPM as Informed Pest Management.Pest Management Science 65(12): 13211328.Google Scholar
Dasgupta, S., Meisner, C., and Wheeler, D. 2007. “Is Environmentally Friendly Agriculture Less Profitable for Growers? Evidence on Integrated Pest Management in Bangladesh.Review of Agricultural Economics 29(1): 103118.CrossRefGoogle Scholar
Environmental Protection Agency. 2011. “Integrated Pest Management Principles” web page. EPA, Washington, D.C. Available at www.epa.gov/pesticides/factsheets/ipm.htm (accessed September 2011).Google Scholar
Fernandez-Cornejo, J.E. 1996. “The Microeconomic Impact of IPM Adoption: Theory and Application.Agricultural and Resource Economics Review 25(2): 149160.Google Scholar
Fernandez-Cornejo, J.E., Beach, D., and Huang, W.Y. 1994. “The Adoption of IPM Technologies by Vegetable Growers in Florida, Michigan, and Texas.Journal of Agricultural and Applied Economics 26(1): 158172.Google Scholar
Florax, R.J.G.M., Travisi, C.M., and Nijkamp, P. 2005. “A Meta-analysis of the Willingness to Pay for Reductions in Pesticide Risk Exposure.European Review of Agricultural Economics 32(4): 441467.CrossRefGoogle Scholar
Govindasamy, R., and Italia, J. 1998. “A Willingness-to-Purchase Comparison of Integrated Pest Management and Conventional Produce.Agribusiness 14(5): 403414.3.0.CO;2-7>CrossRefGoogle Scholar
Mahmoud, C., and Shively, G. 2004. “Agricultural Diversification and Integrated Pest Management in Bangladesh.Agricultural Economics 30(3): 187194.CrossRefGoogle Scholar
Mauceri, M., Alwang, J., Norton, G., and Barrera, V. 2007. “Effectiveness of Integrated Pest Management Dissemination Techniques: A Case Study of Potato Growers in Carchi, Ecuador.Journal of Agricultural and Applied Economics 39(3): 765780.Google Scholar
Mullen, J.D., Reaves, D.W., and Norton, G.W. 1997. “Economic Analysis of Environmental Benefits of Integrated Pest Management.Journal of Agricultural and Applied Economics 29(2): 243253.Google Scholar
Parker, B.L., Skinner, M., Brownbridge, M., and Doubleday, T. 2008. Greenhouse Manager's Guide to Integrated Pest Management in Northern New England. Entomology Research Laboratory, University of Vermont, Burlington, VT.Google Scholar
Ricker-Gilbert, J., Norton, G.W., Alwang, J., Miah, M., and Feder, G. 2008. “Cost-Effectiveness of Alternative Integrated Pest Management Extension Methods: An Example from Bangladesh.Review of Agricultural Economics 30(2): 252269.Google Scholar
Sanderson, J.P. 2006. “Suggestions for Managing Insecticide Resistance in the Greenhouse.Department of Entomology, Cornell University, Ithaca, NY. Available at www.greenhouse.cornell.edu/pests/InsdResistGuide2006.htm (accessed May 2012).Google Scholar
Templeton, D.J., and Jamora, N. 2010. “Economic Assessment of a Change in Pesticide Regulatory Policy in the Philippines.World Development 38(10): 15191526.Google Scholar
Trumble, J.T., Kund, G.S., and Carson, W.G. 1997. “Economics and Environmental Impact of a Sustainable Integrated Pest Management Program in Celery.Journal of Economic Entomology 90(1): 139146.Google Scholar
Vandeman, A., Fernandez-Cornejo, J.E., Jans, S., and Lin, B.H. 1994. Adoption of Integrated Pest Management in U.S. Agriculture. Agricultural Information Bulletin 707, U.S. Department of Agriculture, Washington, D.C.Google Scholar
White, F.C., and Wetzstein, M.E. 1995. “Market Effects of Cotton Integrated Pest Management.American Journal of Agricultural Economics 77(3): 602612.Google Scholar
Williams, G.M., Leidy, R.B., Schal, C., Linker, H.M., and Waldvogel, M.G. 2005. “Comparison of Conventional and Integrated Pest Management Programs in Public Schools.Journal of Economic Entomology 98(4): 12751283.Google Scholar