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Economic impacts of climate change on water resources in the coterminous United States

Author

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  • James Henderson
  • Charles Rodgers
  • Russell Jones
  • Joel Smith
  • Kenneth Strzepek
  • Jeremy Martinich

Abstract

A national-scale simulation-optimization model was created to generate estimates of economic impacts associated with changes in water supply and demand as influenced by climate change. Water balances were modeled for the 99 assessment sub-regions, and are presented for 18 water resource regions in the United States. Benefit functions are developed for irrigated agriculture, municipal and domestic water use, commercial and industrial water use, and hydroelectric power generation. Environmental flows below minimal levels required for environmental needs are assessed a penalty. As a demonstration of concept for the model, future climate is projected using a climate model ensemble for two greenhouse gas (GHG) emissions scenarios: a business-as-usual (BAU) scenario in which no new GHG controls are implemented, and an exemplary mitigation policy (POL) scenario in which future GHG emissions are mitigated. Damages are projected to grow less during the 21st century under the POL scenario than the BAU scenario. The largest impacts from climate change are projected to be on non-consumptive uses (e.g., environmental flows and hydropower) and relatively lower-valued consumptive uses (e.g., agriculture), as water is reallocated during reduced water availability conditions to supply domestic, commercial, and industrial uses with higher marginal values. Lower GHG concentrations associated with a mitigation policy will result in a smaller rise in temperature and thus less extensive damage to some water resource uses. However, hydropower, environmental flow penalty, and agriculture were shown to be sensitive to the change in runoff as well. Copyright The Author(s) 2015

Suggested Citation

  • James Henderson & Charles Rodgers & Russell Jones & Joel Smith & Kenneth Strzepek & Jeremy Martinich, 2015. "Economic impacts of climate change on water resources in the coterminous United States," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 20(1), pages 135-157, January.
    • Handle: RePEc:spr:masfgc:v:20:y:2015:i:1:p:135-157
    DOI: 10.1007/s11027-013-9483-x
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    References listed on IDEAS

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    1. Son H. Kim, Jae Edmonds, Josh Lurz, Steven J. Smith, and Marshall Wise, 2006. "The objECTS Framework for integrated Assessment: Hybrid Modeling of Transportation," The Energy Journal, International Association for Energy Economics, vol. 0(Special I), pages 63-92.
    2. Ronald C. Griffin, 2006. "Water Resource Economics: The Analysis of Scarcity, Policies, and Projects," MIT Press Books, The MIT Press, edition 1, volume 1, number 026207267x, April.
    3. Cai, Ximing & Ringler, Claudia & Rosegrant, Mark W., 2006. "Modeling water resources management at the basin level: methodology and application to the Maipo River Basin," Research reports 149, International Food Policy Research Institute (IFPRI).
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    Cited by:

    1. Radmehr, Riza & Ghorbani, Mohammad & Ziaei, Ali Naghi, 2021. "Quantifying and managing the water-energy-food nexus in dry regions food insecurity: New methods and evidence," Agricultural Water Management, Elsevier, vol. 245(C).
    2. Anil Markandya, 2017. "State of Knowledge on Climate Change, Water, and Economics," World Bank Publications - Reports 26491, The World Bank Group.
    3. J. Sun & Y. P. Li & X. W. Zhuang & S.W. Jin & G. H. Huang & R. F. Feng, 2018. "Identifying water resources management strategies in adaptation to climate change under uncertainty," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 23(4), pages 553-578, April.

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