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Least cost land-use changes for targeted catchment salt load and water yield impacts in south eastern Australia

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  • Nordblom, T.L.
  • Christy, B.P.
  • Finlayson, J.D.
  • Roberts, A.M.
  • Kelly, J.A.

Abstract

This study reports an analysis of the economics of options for strategic land-use change to attain future catchment level target combinations of salt load and water yield. Farm level survey information on land use, productivity, prices and costs of production were integrated with spatially specific soil, rainfall, topography, hydrology and salinity results of the simulation model CAT (Catchment Analysis Tool). This information was used to populate a two stage economic optimization model in which subcatchment economic results were combined for catchment level analyses. This study is the first to exploit CAT results in an economic framework and the first in which economic results are mapped using CAT. The 64,000ha Bet Bet Catchment in Victoria, Australia, once deemed among the highest priority areas in the Murray Darling Basin for dryland salinity reduction, is the focus of this study. The calculated current net present value (NPV) of agricultural production in the catchment is AU$ 78 million3 while providing 42 GL of water yield4 annually for use downstream with a salt load of 22,600t. Results show that salt loads may be reduced to 18,600t (reduction of 4000t) through expansion of tree plantations and lucerne production, reducing water yield to 31 GL (11 GL reduction) and NPV to AU$ 63 million (AU$ 15 million reduction). Water yields could be increased from current levels by 2 GL while maintaining current salt loads. Alternatively, catchment NPV could be increased by approximately AU$ 7 million with little or no reduction in water yield; but there may be reasons (small farm size) why this is unlikely. For this catchment, the maximum reduction in salt load appears insufficient to justify public investment in tree planting and perennial pasture establishment, particularly when the reduced NPV and reduced water yields are taken into account. The results for this catchment do not support regulation of land use for the sake of lowering river salinity. However, the capacity of tree plantations to reduce water yields may support a regulation requiring purchase of water entitlements from downstream entitlement holders for new plantations. Despite millions of dollars of past public investment, it is now clear that Bet Bet Catchment was never one where land-use changes could benefit downstream water users. The approach described in this paper enables catchment management authorities to weigh costs of land-use change against downstream benefits and natural resource management (NRM) options elsewhere.

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  • Nordblom, T.L. & Christy, B.P. & Finlayson, J.D. & Roberts, A.M. & Kelly, J.A., 2010. "Least cost land-use changes for targeted catchment salt load and water yield impacts in south eastern Australia," Agricultural Water Management, Elsevier, vol. 97(6), pages 811-823, June.
    • Handle: RePEc:eee:agiwat:v:97:y:2010:i:6:p:811-823
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    1. Schrobback, Peggy & Adamson, David & Quiggin, John, 2009. "Turning Water into Carbon: Carbon sequestration vs. Water Flow in the Murray Darling Basin," Risk and Sustainable Management Group Working Papers 149877, University of Queensland, School of Economics.
    2. Adamson, David & Mallawaarachchi, Thilak & Quiggin, John C., 2007. "Water use and salinity in the Murray–Darling Basin: A state-contingent model," Australian Journal of Agricultural and Resource Economics, Australian Agricultural and Resource Economics Society, vol. 51(3), pages 1-19.
    3. Nordblom, Thomas L. & Hume, Iain H. & Cresswell, Hamish & Glover, Mark & Hean, Robyn L. & Finlayson, John D. & Wang, Enli, 2007. "Minimising costs of environmental service provision: water-yield, salt-load and biodiversity targets with new tree planting in Simmons Creek Catchment, NSW, a dryland farming/grazing area," 2007 Conference (51st), February 13-16, 2007, Queenstown, New Zealand 10357, Australian Agricultural and Resource Economics Society.
    4. Finlayson, John D. & Bathgate, Andrew D. & Hoque, Ziaul & Nordblom, Thomas L. & Theiveyanathan, Tivi & Crosbie, Russell & Mitchell, David, 2007. "Farm and catchment scale effects of managing dry-land salinity with pastoral and woody perennials," 2007 Conference (51st), February 13-16, 2007, Queenstown, New Zealand 10409, Australian Agricultural and Resource Economics Society.
    5. Nordblom, Thomas L. & Hume, Iain H. & Bathgate, Andrew D. & Reynolds, Michael, 2006. "Mathematical optimisation of drainage and economic land use for target water and salt yields," Australian Journal of Agricultural and Resource Economics, Australian Agricultural and Resource Economics Society, vol. 50(3), pages 1-22, September.
    6. Tom Nordblom & Iain Hume & Andrew Bathgate & Michael Reynolds, 2006. "Mathematical optimisation of drainage and economic land use for target water and salt yields ," Australian Journal of Agricultural and Resource Economics, Australian Agricultural and Resource Economics Society, vol. 50(3), pages 381-402, September.
    7. Young, Michael D. & McColl, James C., 2009. "Double trouble: the importance of accounting for and defining water entitlements consistent with hydrological realities," Australian Journal of Agricultural and Resource Economics, Australian Agricultural and Resource Economics Society, vol. 53(1), pages 1-17.
    8. Nordblom, Thomas L. & Reeson, Andrew & Finlayson, John D. & Hume, Iain H. & Whitten, Stuart M. & Kelly, Jason A., 2009. "Experiments with regulations & markets linking upstream tree plantations with downstream water users," 2009 Conference (53rd), February 11-13, 2009, Cairns, Australia 47945, Australian Agricultural and Resource Economics Society.
    9. Nordblom, Thomas L. & Hume, Iain H. & Finlayson, John D. & Kelly, Jason A. & Welsh, Rob & Hean, Robyn L., 2007. "Downstream benefits vs upstream costs of land use change for water-yield and salt-load targets in the Macquarie Catchment, NSW," 2007 Conference (51st), February 13-16, 2007, Queenstown, New Zealand 10355, Australian Agricultural and Resource Economics Society.
    10. Characklis, Gregory W. & Griffin, Ronald C. & Bedient, Philip B., 2005. "Measuring the Long-Term Regional Benefits of Salinity Reduction," Journal of Agricultural and Resource Economics, Western Agricultural Economics Association, vol. 30(1), pages 1-25, April.
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    Cited by:

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    3. Kathleen H Bowmer, 2013. "Ecosystem Effects from Nutrient and Pesticide Pollutants: Catchment Care as a Solution," Resources, MDPI, vol. 2(3), pages 1-18, September.
    4. Claire Settre & Jeff Connor & Sarah Ann Wheeler, 2017. "Reviewing the Treatment of Uncertainty in Hydro-economic Modeling of the Murray–Darling Basin, Australia," Water Economics and Policy (WEP), World Scientific Publishing Co. Pte. Ltd., vol. 3(03), pages 1-35, July.
    5. Nordblom, T.L. & Hume, I.H. & Finlayson, J.D. & Pannell, D.J. & Holland, J.E. & McClintock, A.J., 2015. "Distributional consequences of upstream tree plantations on downstream water users in a Public–Private Benefit Framework," Agricultural Systems, Elsevier, vol. 139(C), pages 271-281.
    6. Ovando, Paola & Brouwer, Roy, 2019. "A review of economic approaches modeling the complex interactions between forest management and watershed services," Forest Policy and Economics, Elsevier, vol. 100(C), pages 164-176.
    7. Doole, Graeme J., 2012. "Cost-effective policies for improving water quality by reducing nitrate emissions from diverse dairy farms: An abatement–cost perspective," Agricultural Water Management, Elsevier, vol. 104(C), pages 10-20.
    8. Doole, Graeme J. & Marsh, Dan K., 2014. "Methodological limitations in the evaluation of policies to reduce nitrate leaching from New Zealand agriculture," Australian Journal of Agricultural and Resource Economics, Australian Agricultural and Resource Economics Society, vol. 58(1), January.
    9. Nordblom, Tom & Finlayson, John D. & Hume, Iain H. & Kelly, Jason A., 2009. "Supply and Demand for Water use by New Forest Plantations: a market to balance increasing upstream water use with downstream community, industry and environmental use?," Research Reports 280785, New South Wales Department of Primary Industries Research Economists.

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