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Climate change impacts and greenhouse gas mitigation effects on U.S. hydropower generation

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  • Boehlert, Brent
  • Strzepek, Kenneth M.
  • Gebretsadik, Yohannes
  • Swanson, Richard
  • McCluskey, Alyssa
  • Neumann, James E.
  • McFarland, James
  • Martinich, Jeremy

Abstract

Climate change will have potentially significant effects on hydropower generation due to changes in the magnitude and seasonality of river runoff and increases in reservoir evaporation. These physical impacts will in turn have economic consequences through both producer revenues and consumer expenditures. We analyze the physical and economic effects of changes in hydropower generation for the contiguous U.S. in futures with and without global-scale greenhouse gas (GHG) mitigation, and across patterns from 18 General Circulation Models. Using a monthly water resources systems model of 2119 river basins that routes simulated river runoff through reservoirs, and allocates water to potentially conflicting and climate dependent demands, we provide a first-order estimate of the impacts of various projected emissions outcomes on hydropower generation, and monetize these impacts using outputs from an electric sector planning model for over 500 of the largest U.S. hydropower facilities. We find that, due to generally increasing river runoff under higher emissions scenarios in the Pacific Northwest, climate change tends to increase overall hydropower generation in the contiguous U.S. During low flow months, generation tends to fall with increasing emissions, potentially threatening the estimated low flow, firm energy from hydropower. Although global GHG mitigation slows the growth in hydropower generation, the higher value placed on carbon-free hydropower leads to annual economic benefits ranging from $1.8 billion to $4.3 billion. The present value of these benefits to the U.S. from global greenhouse gas mitigation, discounted at 3%, is $34 to $45 billion over the 2015–2050 period.

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  • Boehlert, Brent & Strzepek, Kenneth M. & Gebretsadik, Yohannes & Swanson, Richard & McCluskey, Alyssa & Neumann, James E. & McFarland, James & Martinich, Jeremy, 2016. "Climate change impacts and greenhouse gas mitigation effects on U.S. hydropower generation," Applied Energy, Elsevier, vol. 183(C), pages 1511-1519.
    • Handle: RePEc:eee:appene:v:183:y:2016:i:c:p:1511-1519
    DOI: 10.1016/j.apenergy.2016.09.054
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    1. World Bank, 2010. "The Zambezi River Basin : A Multi-Sector Investment Opportunities Analysis - Modeling, Analysis, and Input Data," World Bank Publications - Reports 2960, The World Bank Group.
    2. DeNooyer, Tyler A. & Peschel, Joshua M. & Zhang, Zhenxing & Stillwell, Ashlynn S., 2016. "Integrating water resources and power generation: The energy–water nexus in Illinois," Applied Energy, Elsevier, vol. 162(C), pages 363-371.
    3. World Bank, 2010. "The Zambezi River Basin : A Multi-Sector Investment Opportunities Analysis - Summary Report," World Bank Publications - Reports 2958, The World Bank Group.
    4. James McFarland & Yuyu Zhou & Leon Clarke & Patrick Sullivan & Jesse Colman & Wendy Jaglom & Michelle Colley & Pralit Patel & Jiyon Eom & Son Kim & G. Kyle & Peter Schultz & Boddu Venkatesh & Juanita , 2015. "Erratum to: Impacts of rising air temperatures and emissions mitigation on electricity demand and supply in the United States: a multi-model comparison," Climatic Change, Springer, vol. 132(4), pages 739-739, October.
    5. Michelle T. H. van Vliet & David Wiberg & Sylvain Leduc & Keywan Riahi, 2016. "Power-generation system vulnerability and adaptation to changes in climate and water resources," Nature Climate Change, Nature, vol. 6(4), pages 375-380, April.
    6. James McFarland & Yuyu Zhou & Leon Clarke & Patrick Sullivan & Jesse Colman & Wendy Jaglom & Michelle Colley & Pralit Patel & Jiyon Eom & Son Kim & G. Kyle & Peter Schultz & Boddu Venkatesh & Juanita , 2015. "Impacts of rising air temperatures and emissions mitigation on electricity demand and supply in the United States: a multi-model comparison," Climatic Change, Springer, vol. 131(1), pages 111-125, July.
    7. World Bank, 2010. "The Zambezi River Basin : A Multi-Sector Investment Opportunities Analysis - State of the Basin," World Bank Publications - Reports 2961, The World Bank Group.
    8. World Bank, 2010. "The Zambezi River Basin : A Multi-Sector Investment Opportunities Analysis - Basin Development Scenarios," World Bank Publications - Reports 2959, The World Bank Group.
    9. Byman Hamududu & Aanund Killingtveit, 2012. "Assessing Climate Change Impacts on Global Hydropower," Energies, MDPI, vol. 5(2), pages 1-18, February.
    10. Schaeffer, Roberto & Szklo, Alexandre Salem & Pereira de Lucena, André Frossard & Moreira Cesar Borba, Bruno Soares & Pupo Nogueira, Larissa Pinheiro & Fleming, Fernanda Pereira & Troccoli, Alberto & , 2012. "Energy sector vulnerability to climate change: A review," Energy, Elsevier, vol. 38(1), pages 1-12.
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