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Social Cost of Biomass Energy from Switchgrass in Western Massachusetts

Published online by Cambridge University Press:  15 September 2016

David Timmons*
Affiliation:
Economics Department at University of Massachusetts Boston
*
Correspondence: David TimmonsEconomics DepartmentUniversity of Massachusetts100 Morrissey BoulevardBoston MA 02125-3393Phone 617.287.6945 ▪ Email [email protected].
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Abstract

Producing biomass energy requires much land, and effects of biomass production on ecosystem services could greatly affect total biomass energy cost. This study estimates switchgrass production cost in western Massachusetts at three levels: private production cost, private cost plus social cost of nitrogen fertilizer externalities, and those costs plus the social opportunity cost of foregone forest ecosystem services. Values for nitrogen externalities and forest ecosystem services estimated with benefit transfer suggest that social cost is much greater than private switchgrass production cost. The benefit-transfer estimates are only first approximations, but conclusions are robust to a large range of values.

Type
Selected Papers
Copyright
Copyright © 2013 Northeastern Agricultural and Resource Economics Association 

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References

Adegbidi, H.G., Volk, T.A., White, E.H., Abrahamson, L.P., Briggs, R.D., and Bickelhaupt, D.H. 2001. “Biomass and Nutrient Removal by Willow Clones in Experimental Bioenergy Plantations in New York State.Biomass and Bioenergy 20(6): 399411.Google Scholar
Antoine, B., Gurgel, A., and Reilly, J.M. 2008. “Will Recreation Demand for Land Limit Biofuels Production?Journal of Agricultural and Food Industrial Organization 6(2).Google Scholar
Babcock, B.A., Gassman, P.W., Jha, M., and Kling, C. 2007. Adoption Subsidies and Environmental Impacts of Alternative Energy Crops. Center for Agricultural and Rural Development, Iowa State University, Ames.Google Scholar
Birch, M.B.L., Gramig, W.R. Moomaw, Doering, O.C.I., and Reeling, C.J. 2011. “Why Metrics Matter: Evaluating Policy Choices for Reactive Nitrogen in the Chesapeake Bay Watershed.Environmental Science and Technology 45: 168174.Google Scholar
Bockstael, N.E., Freeman, A.M. III, Kopp, R.J., Portney, P.R., and Smith, V.K. 2000. “On Measuring Economic Values for Nature.Environmental Science and technology 34(8): 13841389.Google Scholar
Bockstael, N.E., McConnell, K.E., and Strand, I. 1989. “Measuring the Benefits of Improvements in Water Quality: The Chesapeake Bay.Marine Resource Economics 6(1): 118.Google Scholar
Boyle, K.J., and Bergstrom, J.C. 1992. “Benefit Transfer Studies: Myths, Pragmatism, and Idealism.Water Resources Research 28(3): 657663.Google Scholar
Brouwer, R. 2000. “Environmental Value Transfer: State of the Art and Future Prospects.Ecological Economics 32(1): 137152.Google Scholar
Brummer, E.C., Burras, C.L., Duffy, M.D., and Moore, K.J. 2001. Switchgrass Production in Iowa: Economic Analysis, Soil Suitability, and Varietal Performance. Iowa State University, Ames.Google Scholar
Compton, J.N., Harrison, J.A., Dennis, R.L., Greaver, T.L., Hill, B.H., Jordan, S.J., Walker, H., and Campbell, H.V. 2011. “Ecosystem Services Altered by Human Changes in the Nitrogen Cycle: A New Perspective for U.S. Decision Making.Ecology Letters 14(8): 804815.Google Scholar
Conley, D.J., Paerl, H.W., Howarth, R.W., Boesch, D.F., Seitzinger, S.P., Havens, K.E., Lancelot, C., and Likens, G.E. 2009. “Controlling Eutrophication: Nitrogen and Phosphorus.Science 323(5917): 10141015.CrossRefGoogle ScholarPubMed
Costanza, R., d’Arge, R., de Groot, R., Farber, S., Grasso, M., Hannon, B., Limburg, K., Naeem, S., O'Neill, R. V., Paruelo, J., Raskin, R.G., Sutton, P., and van den Belt, M. 1997. “The Value of the World's Ecosystem Services and Natural Capital.Nature 387(6630): 253260.Google Scholar
Costanza, R., Wilson, M., Troy, A., Voinov, A., Liu, S., and D'Agostino, J. 2007. The Value of New Jersey's Ecosystem Services and Natural Capital. The Gund Institute of Ecological Economics, Burlington, Vermont, and The New Jersey Department of Environmental Protection, Trenton, NJ.Google Scholar
Curtis, L., Rea, W., Smith-Willis, P., Fenyves, E., and Pan, Y. 2006. “Adverse Health Effects of Outdoor Air Pollutants.Environment International 32(6): 815830.Google Scholar
Daily, G.C., and Matson, P.A. 2008. “Ecosystem Services: From Theory to Implementation.Proceedings of the National Academy of Sciences 105(28): 94559456.Google Scholar
de Groot, R., Wilson, M.A., and Boumans, R. 2002. “A Typology for the Classification, Description, and Valuation of Ecosystem Functions, Goods, and Services.Ecological Economics 41(3): 393408.Google Scholar
Diaz, R.J., and Rosenberg, R. 2011. “Introduction to Environmental and Economic Consequences of Hypoxia.Water Resources Development 27(1): 7182.Google Scholar
Dodds, W.K., Bouska, W.W., Eitzmann, J.L., Pilger, T.J., Schloesser, J.T., and Thornbrugh, D.J. 2009. “Eutrophication of U.S. Freshwaters: Analysis of Potential Economic Damages.Environmental Science and Technology 43(1): 1219.Google Scholar
Driscoll, C.T., Whitall, D., Aber, J., Boyer, E., Castro, M., Cronan, C., Goodale, C.L., Groffman, P., Hopkinson, C., and Lambert, K. 2003. “Nitrogen Pollution in the Northeastern United States: Sources, Effects, and Management Options.BioScience 53(4): 357374.Google Scholar
Duffy, M.D. 2008. Estimated Costs for Production, Storage, and Transportation of Switchgrass. Iowa State University Extension, Ames, IA.Google Scholar
Eggleston, S., Buendia, L., Miwa, K., Ngara, T., and Tanabe, K. 2006. 2006 IPCC Guidelines for National Greenhouse Gas Inventories. Intergovernmental Panel on Climate Change, Hayama, Japan.Google Scholar
Energy Information Administration. 2011. State Energy Consumption Estimates: 1960 through 2009. Energy Information Administration, Department of Energy, Washington D.C. Google Scholar
Foster, D., Motzkin, G., and Slater, B. 1998. “Land-use History as Long-term Broad-scale Disturbance: Regional Forest Dynamics in Central New England.Ecosystems 1(1): 96119.Google Scholar
Fromm, O. 2000. “Ecological Structure and Functions of Biodiversity as Elements of Its Total Economic Value.Environmental and Resource Economics 16(3): 303328.CrossRefGoogle Scholar
Galloway, J.N., Aber, J.D., Erisman, J.W., Seitzinger, S.P., Howarth, R.B., Cowling, E.B., and Crosby, B.J. 2003. “The Nitrogen Cascade.BioScience 53(4): 341356.CrossRefGoogle Scholar
Grinsven, H.J., Rabl, A., and de Kok, T.M. 2010. “Estimation of Incidence and Social Cost of Colon Cancer due to Nitrate in Drinking Water in the EU: A Tentative Cost-Benefit Assessment.Environmental Health 9(58).Google Scholar
Guo, Z., Xiao, X., and Li, D. 2000. “An Assessment of Ecosystem Services: Water Flow Regulation and Hydroelectric Power Production.Ecological Applications 10(3): 925936.Google Scholar
Haq, Z. 2002. Biomass for Electricity Generation. Energy Information Administration, U.S. Department of Energy, Washington D.C. Google Scholar
Haque, M., Biermacher, J.T., Kering, M.K., and Guretzky, J.A. (2012). Managing Nitrogen and Phosphorus Nutrients for Switchgrass Produced for Bioenergy Feedstock in Phosphorous-deficient Soil. Southern Agricultural Economics Association Annual Meeting, Birmingham, AL.Google Scholar
Hill, J. 2007. “Environmental Costs and Benefits of Transportation Biofuel Production from Food- and Lignocellulose-based Energy Crops. A Review.Agronomy for Sustainable Development 27(1): 112.Google Scholar
Innovative Natural Resource Solutions. 2007. Biomass Availability Analysis: Five Counties of Western Massachusetts. Massachusetts Division of Energy Resources, Boston, MA.Google Scholar
Kelty, M.J., D'Amato, A. W., and Barten, P.K. 2008. Silvicultural and Ecological Considerations of Forest Biomass Harvesting in Massachusetts. University of Massachusetts, Amherst MA.Google Scholar
Kilfoy, B.A., Zhang, Y., Park, Y., Holford, T.R., Schatzkin, A., Hollenbeck, A., and Ward, M.H. 2011. “Dietary Nitrate and Nitrite and the Risk of Thyroid Cancer in the NIH-AARP Diet and Health Study.International Journal of Cancer 129(1): 160172.Google Scholar
Kiniry, J.R., Cassida, K.A., Hussey, M.A., Muir, J.P., Ocumpaugh, W.R., Read, J.C., Reed, R.L., Sanderson, M.A., Venuto, B.C., and Williams, J.R. 2005. “Switchgrass Simulation by the ALMANAC Model at Diverse Sites in the Southern U.S.Biomass and Bioenergy 29(6): 419425.Google Scholar
Kiniry, J.R., Lynd, L., Greene, N., Johnson, M.-V.V., Casler, M., and Laser, M.S. 2008a. “Biofuels and Water Use: Comparison of Maize and Switchgrass and General Perspectives”. In Wright, J.H. and Evans, D.A., eds., New Research on Biofuels, Nova Science Publishers.Google Scholar
Kiniry, J.R., Schmer, M.R., Vogel, K.P., and Mitchell, R.B. 2008b. “Switchgrass Biomass Simulation at Diverse Sites in the Northern Great Plains of the U.S.Bioenergy Research 1(3/4): 259264.CrossRefGoogle Scholar
Kiniry, J.R., Williams, J.R., Gassman, P.W., and Debaek, P. 1992. “A General, Process-oriented Model for Two Competing Plant Species.Transactions of the ASAE 35(3): 801810.Google Scholar
Kusiima, J.M., and Powers, S.E. 2010. “Monetary Value of the Environmental and Health Externalities associated with Production of Ethanol from Biomass Feedstocks.Energy Policy 38(6): 27852796.Google Scholar
Lemus, R., Brummer, E.C., Burras, C.L., Moore, K.J., Barker, M.F., and Molstad, N.E. 2008. “Effects of Nitrogen Fertilization on Biomass Yield and Quality in Large Fields of Established Switchgrass in Southern Iowa, USA.Biomass and Bioenergy 32(12): 11871194.Google Scholar
Lemus, R., and Lal, R. 2005. “Bioenergy Crops and Carbon Sequestration.Critical Reviews in Plant Sciences 24(1): 121.Google Scholar
Liu, S., Costanza, R., Troy, A., D’Agostino, J., and Mates, W. 2010. “Valuing New Jersey's Ecosystem Services and Natural Capital: A Spatially Explicit Benefit Transfer Approach.Environmental management 45(6): 12711285.Google Scholar
Loomis, J.B., and Rosenberger, R.S. 2006. “Reducing Barriers in Future Benefit Transfers: Needed Improvements in Primary Study Design and Reporting.Ecological Economics 60(2): 343350.Google Scholar
McLaughlin, S.B., Samson, R., Bransby, D.I., and Wiselogel, A. 1996. Evaluating Physical, Chemical, and Energetic Properties of Perennial Grasses as Biofuels. BIOENERGY ‘96, The seventh national bioenergy conference, Nashville, TN.Google Scholar
Mikkelsen, R. 2009. “Ammonia Emissions from Agricultural Operations: Fertilizer.Better Crops with Plant Food 93(4): 911.Google Scholar
Morgan, C., and Owens, N. 2001. “Benefits of Water Quality Policies: The Chesapeake Bay.Ecological Economics 39(2): 271284.Google Scholar
Nelson, R.G., Ascough, J.C.I., and Langemeier, M.R. 2006. “Environmental and Economic Analysis of Switchgrass Production for Water Quality Improvement in Northeast Kansas.Journal of Environmental Management 79(4): 336347.Google Scholar
New Hampshire Timberland Owners Association. 2011. Timber Crier, 4th quarter.Google Scholar
Nunes, P.A.L.D., and J.C.J.M. van den Bergh. 2001. “Economic Valuation of Biodiversity: Sense or Nonsense?Ecological Economics 39(2): 203222.Google Scholar
Pearce, D. 1998. “Auditing the Earth.Environment 40(2): 2328.Google Scholar
Perlack, R.D., Wright, L.L., Turhollow, A.F., Graham, R.L., Stokes, B.J., and Erbach, D.C. 2005. Biomass as Feedstock for a Bioenergy and Bioproducts Industry: The Technical Feasibility of a Billion-ton Annual Supply. U.S. Department of Agriculture, Washington, D.C. Google Scholar
Pimentel, D., Herz, M., Glickstein, M., Zimmerman, M., Allen, R., Becker, K., Evans, J., Hussain, B., Sarsfeld, R., Grosfeld, A., and Seidel, T. 2002. “Renewable Energy: Current and Potential Issues.BioScience 52(12): 11111120.Google Scholar
Powers, S.E. 2007. “Nutrient Loads to Surface Water from Row Crop Production.International Journal of Life Cycle Assessment 12(6): 399407.CrossRefGoogle Scholar
Powlson, D.S., Addiscott, T.M., Benjamin, N., Cassman, K.G., De Kok, T.M., Van Grinsven, H., L'hirondel, J.L., Avery, A.A., and Van Kessel, C. 2008. “When Does Nitrate Become a Risk for Humans?Journal of environmental quality 37(2): 291295.Google Scholar
Russell, H.S., and Lapping, M. 1982. A Long, Deep Furrow: Three Centuries of Farming in New England. Hanover, NH: University Press of New England.Google Scholar
Solomon, S., Qin, D., Manning, M., Chen, Z., Marquis, M., Averyt, K.B., Tignor, M., and Miller, H.L. 2007. Climate Change 2007: Working Group I Report: The Physical Science Basis. Cambridge, UK: Cambridge University Press.Google Scholar
Stern, N. 2006. The Economics of Climate Change: The Stern Review. Cambridge, UK: Cambridge University Press.Google Scholar
Timmons, D. 2011. “The Potential Supply of Cellulosic Biomass Crops in Massachusetts.” Ph.D. dissertation, Department of Resource Economics, University of Massachusetts Amherst.Google Scholar
Timmons, D. 2012. “Estimating a Technically Feasible Switchgrass Supply Function: A Western Massachusetts Example.Bioenergy Research 5(1): 236246.Google Scholar
Timmons, D., Damery, D., Allen, G., and Petraglia, L. 2007. Energy from Forest Biomass: Potential Economic Impacts in Massachusetts. Massachusetts Department of Energy Resources, Boston, MA.Google Scholar
Tol, R. 2008. “The Social Cost of Carbon: Trends, Outliers, and Catastrophes.Economics: The Open-Access, Open-Assessment E-Journal 2(25): 122.Google Scholar
Turner, R.K., and Daily, G.C. 2008. “The Ecosystem Services Framework and Natural Capital Conservation.Environmental and Resource Economics 39(1): 2535.Google Scholar
USDA/Pennsylvania Department of Agriculture. 2009. 2009 Machinery Custom Rates. Pennsylvania Department of Agriculture, Harrisburg, PA.Google Scholar
Van Breemen, N., Boyer, E.W., Goodale, C.L., Jaworski, N.A., Paustian, K., Seitzinger, S.P., Lajtha, K., Mayer, B., Van Dam, D., Howarth, R.W., Nadelhoffer, K.J., Eve, M., and Billen, G. 2002. “Where Did All the Nitrogen Go? Fate of Nitrogen Inputs to Large Watersheds in the Northeastern U.S.A.Biogeochemistry 57/58(1): 267293.Google Scholar
Veldkamp, E., and Keller, M. 1997. “Fertilizer-induced Nitric Oxide Emissions from Agricultural Soils.Nutrient Cycling in Agroecosystems 48(1/2): 6977.Google Scholar
Williams, J.R., Arnold, J.G., Kiniry, J.R., Gassman, P.W., and Green, C.H. 2008. “History of Model Development at Temple, Texas.Hydrological Sciences 53(5): 948960.Google Scholar
Williams, P.R.D., Inman, D., Aden, A., and Heath, G.A. 2009. “Environmental and Sustainability Factors Associated with Next-generation Biofuels in the U.S: What Do We Really Know?Environmental science & technology 43(13): 47634775.Google Scholar
Zhang, W., Ricketts, T.H., Kremen, C., Carney, K., and Swinton, S.M. 2007. “Ecosystem Services and Dis-services to Agriculture.Ecological Economics 64(2): 253260.Google Scholar