Economic perspectives on nitrogen in farming systems: managing trade-offs between production, risk and the environment
David J. PannellCentre for Environmental Economics and Policy, University of Western Australia, 35 Stirling Highway, Crawley WA 6009, Australia. Email: david.pannell@uwa.edu.au
Soil Research 55(6) 473-478 https://doi.org/10.1071/SR16284
Submitted: 24 October 2016 Accepted: 12 May 2017 Published: 15 June 2017
Abstract
Economic insights are crucial for making sound decisions about farm-level management of nitrogen and also about regional or national policy such as for water pollution. In the present review, key insights are presented from a large and diverse literature on the economics of nitrogen in agriculture and the economics of the consequences of nitrogen fertilisation. Issues covered include (1) the economics of nitrogen as an input to production, (2) nitrogen and economic risk at the farm level, (3) the economics of nitrogen fixation by legumes, (4) the existence of flat payoff functions, which often allow wide flexibility in decisions about nitrogen fertiliser rates, (5) explanations for over-application of nitrogen fertilisers by some farmers, and (6) the economics of nitrogen pollution at both the farm level and the policy level. Economics helps to explain farmer behaviour and to design strategies and policies that are more beneficial and more likely to be adopted and successfully implemented.
Additional keywords: economics, optimisation, policy, pollution, profit.
References
Abadi Ghadim AK, Pannell DJ (2003) Risk attitudes and risk perceptions of crop producers in Western Australia. In ‘Risk management and the environment: agriculture in perspective’. (Eds BA Babcock, RW Fraser, JN Lekakis) pp. 113–133. (Kluwer: Dordrecht, The Netherlands)Alston JM, Norton GW, Pardey PG (1995) ‘Science under scarcity: principles and practice for agricultural research evaluation and priority setting.’ (Cornell University Press: Ithaca)
Anderson JR (1975) One more or less cheer for optimality. Journal of the Australian Institute of Agricultural Science 41, 195–197.
Andréasson IM (1990) Costs for reducing farmers’ use of nitrogen in Gotland, Sweden. Ecological Economics 2, 287–299.
| Costs for reducing farmers’ use of nitrogen in Gotland, Sweden.Crossref | GoogleScholarGoogle Scholar |
Antle JM (1987) Econometric estimation of producers’ risk attitudes. American Journal of Agricultural Economics 69, 509–522.
| Econometric estimation of producers’ risk attitudes.Crossref | GoogleScholarGoogle Scholar |
Babcock BA, Pautsch GR (1998) Moving from uniform to variable fertilizer rates on Iowa corn: effects on rates and returns. Journal of Agricultural and Resource Economics 23, 385–400.
Binswanger HP (1980) Attitudes toward risk: experimental measurement in rural India. American Journal of Agricultural Economics 62, 395–407.
| Attitudes toward risk: experimental measurement in rural India.Crossref | GoogleScholarGoogle Scholar |
Bostian M, Whittaker G, Barnhart B, Färe R, Grosskopf S (2015) Valuing water quality tradeoffs at different spatial scales: an integrated approach using bilevel optimization. Water Resources and Economics 11, 1–12.
| Valuing water quality tradeoffs at different spatial scales: an integrated approach using bilevel optimization.Crossref | GoogleScholarGoogle Scholar |
Byström O (1998) The nitrogen abatement cost in wetlands. Ecological Economics 26, 321–331.
| The nitrogen abatement cost in wetlands.Crossref | GoogleScholarGoogle Scholar |
Cooper JC, Keim RW (1996) Incentive payments to encourage farmer adoption of water quality protection practices. American Journal of Agricultural Economics 78, 54–64.
| Incentive payments to encourage farmer adoption of water quality protection practices.Crossref | GoogleScholarGoogle Scholar |
Dabrowski JM, Murray K, Ashton PJ, Leaner JJ (2009) Agricultural impacts on water quality and implications for virtual water trading decisions. Ecological Economics 68, 1074–1082.
| Agricultural impacts on water quality and implications for virtual water trading decisions.Crossref | GoogleScholarGoogle Scholar |
Dillon JL, Anderson JR (2012) ‘The analysis of response in crop and livestock production.’ 3rd edn. (Pergamon: Oxford)
Doole GJ, Romero AJ (2014) Cost-effective regulation of nonpoint emissions from pastoral agriculture: a stochastic analysis. The Australian Journal of Agricultural and Resource Economics 58, 471–494.
| Cost-effective regulation of nonpoint emissions from pastoral agriculture: a stochastic analysis.Crossref | GoogleScholarGoogle Scholar |
Doole GJ, Romero AJ (2015) Trade-offs between profit, production, and environmental footprint on pasture-based dairy farms in the Waikato region of New Zealand. Agricultural Systems 141, 14–23.
| Trade-offs between profit, production, and environmental footprint on pasture-based dairy farms in the Waikato region of New Zealand.Crossref | GoogleScholarGoogle Scholar |
Drucker AG, Latacz-Lohmann U (2003) Getting incentives right?: a comparative analysis of policy instruments for livestock waste pollution abatement in Yucatán, Mexico. Environment and Development Economics 8, 261–284.
| Getting incentives right?: a comparative analysis of policy instruments for livestock waste pollution abatement in Yucatán, Mexico.Crossref | GoogleScholarGoogle Scholar |
England RA (1986) Reducing the nitrogen input on arable farms. Journal of Agricultural Economics 37, 13–24.
| Reducing the nitrogen input on arable farms.Crossref | GoogleScholarGoogle Scholar |
Fleming RA, Adams RM, Ervin DE (1998) The role of soil test information in reducing groundwater pollution. Journal of Agricultural and Resource Economics 23, 20–38.
Fröschl L, Pierrard R, Schönbäck W (2008) Cost-efficient choice of measures in agriculture to reduce the nitrogen load flowing from the Danube River into the Black Sea. An analysis for Austria, Bulgaria, Hungary and Romania. Ecological Economics 68, 96–105.
| Cost-efficient choice of measures in agriculture to reduce the nitrogen load flowing from the Danube River into the Black Sea. An analysis for Austria, Bulgaria, Hungary and Romania.Crossref | GoogleScholarGoogle Scholar |
Gren IM (2001) International versus national actions against nitrogen pollution of the Baltic Sea. Environmental and Resource Economics 20, 41–59.
| International versus national actions against nitrogen pollution of the Baltic Sea.Crossref | GoogleScholarGoogle Scholar |
Hansen LG (1999) A deposit–refund system applied to non-point nitrogen emissions from agriculture. Environmental Economics and Policy Studies 2, 231–247.
| A deposit–refund system applied to non-point nitrogen emissions from agriculture.Crossref | GoogleScholarGoogle Scholar |
Hanson JC, McConnell KE (2008) Simulated trading for Maryland’s nitrogen loadings in the Chesapeake Bay. Agricultural and Resource Economics Review 37, 211–226.
| Simulated trading for Maryland’s nitrogen loadings in the Chesapeake Bay.Crossref | GoogleScholarGoogle Scholar |
Hasler B, Smart JCR, Fonnesbech-Wulff A, Andersen HE, Thodsen H, Blicher Mathiesen G, Smedberg E, Göke C, Czajkowski M, Was A, Elofsson K, Humborg C, Wolfsberg A, Wulff F (2014) Hydro-economic modelling of cost-effective transboundary water quality management in the Baltic Sea. Water Resources and Economics 5, 1–23.
| Hydro-economic modelling of cost-effective transboundary water quality management in the Baltic Sea.Crossref | GoogleScholarGoogle Scholar |
Helin JA (2014) Reducing nutrient loads from dairy farms: a bioeconomic model with endogenous feeding and land use. Agricultural Economics 45, 167–184.
| Reducing nutrient loads from dairy farms: a bioeconomic model with endogenous feeding and land use.Crossref | GoogleScholarGoogle Scholar |
Hendricks NP, Sinnathamby S, Douglas-Mankin K, Smith A, Sumner DA, Earnhart DH (2014) The environmental effects of crop price increases: nitrogen losses in the U.S. Corn Belt. Journal of Environmental Economics and Management 68, 507–526.
| The environmental effects of crop price increases: nitrogen losses in the U.S. Corn Belt.Crossref | GoogleScholarGoogle Scholar |
Huang WY, Hewitt TI, Shank D (1998) An analysis of on-farm costs of timing N applications to reduce N losses. Journal of Agricultural and Resource Economics 23, 445–467.
Huang J, Huang Z, Jia X, Hu R, Xiang C (2015) Long-term reduction of nitrogen fertilizer use through knowledge training in rice production in China. Agricultural Systems 135, 105–111.
| Long-term reduction of nitrogen fertilizer use through knowledge training in rice production in China.Crossref | GoogleScholarGoogle Scholar |
Hyytiäinen K, Ahlvik L, Ahtiainen H, Artell J, Huhtala A, Dahlbo K (2015) Policy goals for improved water quality in the Baltic Sea: when do the benefits outweigh the costs? Environmental and Resource Economics 61, 217–241.
| Policy goals for improved water quality in the Baltic Sea: when do the benefits outweigh the costs?Crossref | GoogleScholarGoogle Scholar |
Jardine R (1975) Two cheers for optimality. Journal of the Australian Institute of Agricultural Science 41, 30–34.
Johnson SL, Adams RM, Perry GM (1991) The on-farm costs of reducing groundwater pollution. American Journal of Agricultural Economics 73, 1063–1073.
| The on-farm costs of reducing groundwater pollution.Crossref | GoogleScholarGoogle Scholar |
Kingwell RS, Pannell DJ (Eds) (1987) ‘MIDAS, A bioeconomic model of a dryland farm system.’ (Pudoc: Wageningen)
Knapp KC, Schwabe KA (2008) Spatial dynamics of water and nitrogen management in irrigated agriculture. American Journal of Agricultural Economics 90, 524–539.
| Spatial dynamics of water and nitrogen management in irrigated agriculture.Crossref | GoogleScholarGoogle Scholar |
Konrad MT, Andersen HE, Thodsen H, Termansen M, Hasler B (2014) Cost-efficient reductions in nutrient loads; identifying optimal spatially specific policy measures. Water Resources and Economics 7, 39–54.
| Cost-efficient reductions in nutrient loads; identifying optimal spatially specific policy measures.Crossref | GoogleScholarGoogle Scholar |
Lansink AO, Peerlings J (1997) Effects of N-surplus taxes: combining technical and historical information. European Review of Agriculture Economics 24, 231–247.
| Effects of N-surplus taxes: combining technical and historical information.Crossref | GoogleScholarGoogle Scholar |
Llewellyn RS, Lindner RK, Pannell DJ, Powles SB (2005) Targeting key perceptions when planning and evaluating extension. Australian Journal of Experimental Agriculture 45, 1627–1633.
| Targeting key perceptions when planning and evaluating extension.Crossref | GoogleScholarGoogle Scholar |
Mazid A, Bailey E (1992) Incorporating risk in the economic analysis of agronomic trials: fertilizer use on barley in Syria. Agricultural Economics 7, 167–184.
| Incorporating risk in the economic analysis of agronomic trials: fertilizer use on barley in Syria.Crossref | GoogleScholarGoogle Scholar |
Monjardino M, McBeath T, Ouzman J, Llewellyn R, Jones B (2015) Farmer risk-aversion limits closure of yield and profit gaps: a study of nitrogen management in the southern Australian wheatbelt. Agricultural Systems 137, 108–118.
| Farmer risk-aversion limits closure of yield and profit gaps: a study of nitrogen management in the southern Australian wheatbelt.Crossref | GoogleScholarGoogle Scholar |
Morgan C, Owens N (2001) Benefits of water quality policies: the Chesapeake Bay. Ecological Economics 39, 271–284.
| Benefits of water quality policies: the Chesapeake Bay.Crossref | GoogleScholarGoogle Scholar |
Morrison DA, Kingwell RS, Pannell DJ, Ewing MA (1986) A mathematical programming model of a crop-livestock farm system. Agricultural Systems 20, 243–268.
| A mathematical programming model of a crop-livestock farm system.Crossref | GoogleScholarGoogle Scholar |
Moxey A, White B (1994) Efficient compliance with agricultural nitrate pollution standards. Journal of Agricultural Economics 45, 27–37.
| Efficient compliance with agricultural nitrate pollution standards.Crossref | GoogleScholarGoogle Scholar |
Nkonya EM, Featherstone AM (2000) Determining socially optimal nitrogen application rates using a delayed response model: the case of irrigated corn in Western Kansas. Journal of Agricultural and Resource Economics 25, 453–467.
Pannell DJ (1995) Economic aspects of legume management and legume research in dryland farming systems of southern Australia. Agricultural Systems 49, 217–236.
| Economic aspects of legume management and legume research in dryland farming systems of southern Australia.Crossref | GoogleScholarGoogle Scholar |
Pannell DJ (2006) Flat-earth economics: the far-reaching consequences of flat payoff functions in economic decision making. Review of Agricultural Economics 28, 553–566.
| Flat-earth economics: the far-reaching consequences of flat payoff functions in economic decision making.Crossref | GoogleScholarGoogle Scholar |
Pannell DJ (2008) Public benefits, private benefits, and policy intervention for land-use change for environmental benefits. Land Economics 84, 225–240.
| Public benefits, private benefits, and policy intervention for land-use change for environmental benefits.Crossref | GoogleScholarGoogle Scholar |
Pannell DJ, Falconer DA (1988) The relative contributions to profit of fixed and applied nitrogen in a crop-livestock farm system. Agricultural Systems 26, 1–17.
| The relative contributions to profit of fixed and applied nitrogen in a crop-livestock farm system.Crossref | GoogleScholarGoogle Scholar |
Pannell DJ, Marshall GR, Barr N, Curtis A, Vanclay F, Wilkinson R (2006) Understanding and promoting adoption of conservation practices by rural landholders. Australian Journal of Experimental Agriculture 46, 1407–1424.
| Understanding and promoting adoption of conservation practices by rural landholders.Crossref | GoogleScholarGoogle Scholar |
Pannell DJ, Llewellyn RS, Corbeels M (2014) The farm-level economics of conservation agriculture for resource-poor farmers. Agriculture, Ecosystems & Environment 187, 52–64.
| The farm-level economics of conservation agriculture for resource-poor farmers.Crossref | GoogleScholarGoogle Scholar |
Paz JO, Batchelor WD, Babcock BA, Colvin TS, Logsdon SD, Kaspar TC, Karlen DL (1999) Model-based technique to determine variable rate nitrogen for corn. Agricultural Systems 61, 69–75.
| Model-based technique to determine variable rate nitrogen for corn.Crossref | GoogleScholarGoogle Scholar |
Poor PJ, Pessagno KL, Paul RW (2007) Exploring the hedonic value of ambient water quality: a local watershed-based study. Ecological Economics 60, 797–806.
| Exploring the hedonic value of ambient water quality: a local watershed-based study.Crossref | GoogleScholarGoogle Scholar |
Preckel PV, Shively GE, Baker TG, Chu MC, Burrell JE (2000) Contract incentives and excessive nitrogen use in agriculture. Journal of Agricultural and Resource Economics 2, 468–484.
Preissel S, Reckling M, Schläfke N, Zander P (2015) Magnitude and farm-economic value of grain legume pre-crop benefits in Europe: a review. Field Crops Research 175, 64–79.
| Magnitude and farm-economic value of grain legume pre-crop benefits in Europe: a review.Crossref | GoogleScholarGoogle Scholar |
Rajsic P, Weersink A (2008) Do farmers waste fertilizer? A comparison of ex post optimal nitrogen rates and ex ante recommended rates by model, site and year. Agricultural Systems 97, 56–67.
| Do farmers waste fertilizer? A comparison of ex post optimal nitrogen rates and ex ante recommended rates by model, site and year.Crossref | GoogleScholarGoogle Scholar |
Rajsic P, Weersink A, Gandorfer M (2009) Risk and nitrogen application levels. Canadian Journal of Agricultural Economics 57, 223–239.
| Risk and nitrogen application levels.Crossref | GoogleScholarGoogle Scholar |
Ribaudo MO, Heimlich R, Claassen R, Peters M (2001) Least-cost management of nonpoint source pollution: source reduction versus interception strategies for controlling nitrogen loss in the Mississippi Basin. Ecological Economics 37, 183–197.
| Least-cost management of nonpoint source pollution: source reduction versus interception strategies for controlling nitrogen loss in the Mississippi Basin.Crossref | GoogleScholarGoogle Scholar |
Roosen J, Hennessy DA (2003) Tests for the role of risk aversion on input use. American Journal of Agricultural Economics 85, 30–43.
| Tests for the role of risk aversion on input use.Crossref | GoogleScholarGoogle Scholar |
Schilizzi S, Pannell DJ (2001) The economics of nitrogen fixation. Agronomie 21, 527–537.
| The economics of nitrogen fixation.Crossref | GoogleScholarGoogle Scholar |
Sheriff G (2005) Efficient waste? Why farmers over-apply nutrients and the implications for policy design. Review of Agricultural Economics 27, 542–557.
| Efficient waste? Why farmers over-apply nutrients and the implications for policy design.Crossref | GoogleScholarGoogle Scholar |
Thrikawala S, Weersink A, Kachanoski G, Fox G (1999) Economic feasibility of variable-rate technology for nitrogen on corn. American Journal of Agricultural Economics 81, 914–927.
| Economic feasibility of variable-rate technology for nitrogen on corn.Crossref | GoogleScholarGoogle Scholar |
Vatn A, Bakken LR, Lundeby H, Romstad E, Rørstad PKr, Vold A, Botterweg P (1997) Regulating nonpoint-source pollution from agriculture: an integrated modelling analysis. European Review of Agriculture Economics 24, 207–229.
| Regulating nonpoint-source pollution from agriculture: an integrated modelling analysis.Crossref | GoogleScholarGoogle Scholar |
Vermersch D, Bonnieux F, Rainelli P (1993) Abatement of agricultural pollution and economic incentives: the case of intensive livestock farming in France. Environmental and Resource Economics 3, 285–296.
| Abatement of agricultural pollution and economic incentives: the case of intensive livestock farming in France.Crossref | GoogleScholarGoogle Scholar |
Weersink A, Dutka C, Goss M (1998) Crop price and risk effects on farm abatement costs. Canadian Journal of Agricultural Economics 46, 171–190.
| Crop price and risk effects on farm abatement costs.Crossref | GoogleScholarGoogle Scholar |
Wu J, Tanaka K (2005) Reducing nitrogen runoff from the upper Mississippi River basin to control hypoxia in the Gulf of Mexico: easements or taxes? Marine Resource Economics 20, 121–144.
| Reducing nitrogen runoff from the upper Mississippi River basin to control hypoxia in the Gulf of Mexico: easements or taxes?Crossref | GoogleScholarGoogle Scholar |