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Using Nitrogen Fertilizer to Grow Irrigated Cotton in Australia: Marginal Benefits and Costs of Nitrogen and Nitrous Oxide Emissions

Author

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  • Rathnayake, Chinthani
  • Malcolm, Bill
  • Griffith, Garry
  • Sinnett, Alex
  • Deane, Paul

Abstract

The nitrogen (N) fertilizer used to help grow fully irrigated cotton in Australia adds, through several pathways, nitrous oxide (N2O) to the stock of nitrous oxide in the atmosphere and increases the global externality cost of the warming climate. The focus of this analysis is on the extra social benefits and the extra private costs and negative externality costs of using different quantities of N on land in NSW and QLD to grow cotton over a year, and over the coming 15 years, as compared with not growing cotton on that land and replacing the activity with another economic activity. Starting at the farm, a welfare economics framework including the concepts of response of crop yield to N fertiliser, private costs, externality costs, marginality, with-without counterfactuals, opportunity costs, crop rotations, discounting, probabilities, consumer surplus, producer surplus and net social benefit are used to estimate the size of the social benefits and costs of N used to grow irrigated cotton. In the case analysed, with an illustrative counterfactual, the externality cost of direct N2O emissions from growing cotton after counting for the counterfactual was $102/ha yielding a Benefit to Cost (B:C) ratio of 7.2:1. The net social benefit on the industry over 15 years at a 5 per cent real discount rate per annum in net present value terms was $5.6 billion with an annuity of $541 million. In the case analysed and with the probabilities assumed for the values that the key uncertain variables could take, with only direct N2O emissions counted as the negative externality of the N used, there would be a 90 per cent probability that the B:C ratio of N used to grow cotton was between 5.4:1 and 9.6:1. There would be 55 per cent chance the B:C ratio would be more than 7:1. There would be zero chance the B:C ratio would be under 4:1. A significant finding about the negative externality of the N2O emissions from the N applied to cotton was that $80 of the $116/ha externality cost from the N2O emissions came from the marginal 50 kg of N/ha that was used. If the response function is relatively flat around the typical level of N/ha that is used in a typical year, then the marginal units of N applied would be adding little extra cotton yield relative to the extra externality cost attributable to the N2O emissions. In this situation, there would be scope for small reductions in N/ha used to grow extra cotton to bring large reductions in the externality cost of the N2O emissions from N used to grow cotton.

Suggested Citation

  • Rathnayake, Chinthani & Malcolm, Bill & Griffith, Garry & Sinnett, Alex & Deane, Paul, 2023. "Using Nitrogen Fertilizer to Grow Irrigated Cotton in Australia: Marginal Benefits and Costs of Nitrogen and Nitrous Oxide Emissions," AFBM Journal, Australasian Farm Business Management Network, vol. 20(4), October.
    • Handle: RePEc:ags:afbmau:341182
    DOI: 10.22004/ag.econ.341182
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    References listed on IDEAS

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    1. Godard, C. & Roger-Estrade, J. & Jayet, P.A. & Brisson, N. & Le Bas, C., 2008. "Use of available information at a European level to construct crop nitrogen response curves for the regions of the EU," Agricultural Systems, Elsevier, vol. 97(1-2), pages 68-82, April.
    2. Stott, Kerry J. & Malcolm, Bill & Gourley, Cameron J.P. & Hannah, Murray C. & Cox, Matthew, 2018. "The ‘Dairy Nitrogen Fertiliser Advisor’ - a method of testing farmers’ fertiliser decisions against a meta-analysis N-response function," AFBM Journal, Australasian Farm Business Management Network, vol. 15, December.
    3. David J. Pannell, 2006. "Flat Earth Economics: The Far-reaching Consequences of Flat Payoff Functions in Economic Decision Making," Review of Agricultural Economics, Agricultural and Applied Economics Association, vol. 28(4), pages 553-566.
    4. Rausser, Gordon C. & Moriak, Theo F., 1970. "The Demand for Fertilizer, 1949-64: An Analysis of Coefficients From Periodic Cross Sections," Journal of Agricultural Economics Research, United States Department of Agriculture, Economic Research Service, vol. 22(2), pages 1-12, April.
    5. Welsh, Jon & Powell, Janine & Scott, Fiona, 2015. "Optimising nitrogen fertiliser in high yielding irrigated cotton: A benefit-cost analysis and the feasibility of participation in the ERF," AFBM Journal, Australasian Farm Business Management Network, vol. 12, December.
    6. Zvi Griliches, 1958. "The Demand for Fertilizer: An Economic Interpretation of a Technical Change," American Journal of Agricultural Economics, Agricultural and Applied Economics Association, vol. 40(3), pages 591-606.
    7. Breen, James P. & Clancy, Daragh & Donnellan, Trevor & Hanrahan, Kevin F., 2012. "Estimating the Elasticity of Demand and the Production Response for Nitrogen Fertiliser on Irish Farms," 86th Annual Conference, April 16-18, 2012, Warwick University, Coventry, UK 134965, Agricultural Economics Society.
    8. Williamson, James M., 2011. "The Role of Information and Prices in the Nitrogen Fertilizer Management Decision: New Evidence from the Agricultural Resource Management Survey," Journal of Agricultural and Resource Economics, Western Agricultural Economics Association, vol. 36(3), pages 1-21.
    9. Higgins, James, 1986. "Input Demand and Output Supply on Irish Farms--A Micro-economic Approach," European Review of Agricultural Economics, Oxford University Press and the European Agricultural and Applied Economics Publications Foundation, vol. 13(4), pages 477-493.
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