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Predicting thermal vulnerability of stream and river ecosystems to climate change

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  • Ryan Hill
  • Charles Hawkins
  • Jiming Jin

Abstract

We use a predictive model of mean summer stream temperature to assess the vulnerability of USA streams to thermal alteration associated with climate change. The model uses air temperature and watershed features (e.g., watershed area and slope) from 569 US Geological Survey sites in the conterminous USA to predict stream temperatures. We assess the model for predicting climate-related variation in stream temperature by comparing observed and predicted historical stream temperature changes. Analysis of covariance confirms that observed and predicted changes in stream temperatures respond similarly to historical changes in air temperature. When applied to spatially-downscaled future air temperature projections (A2 emission scenario), the model predicts mean warming of 2.2 °C for the conterminous USA by 2100. Stream temperatures are most responsive to climate changes in the Cascade and Appalachian Mountains and least responsive in the southeastern USA. We then use random forests to conduct an empirical sensitivity analysis to identify those stream features most strongly associated with both observed historical and predicted future changes in summer stream temperatures. Larger changes in stream temperature are associated with warmer future air temperatures, greater air temperature changes, and larger watershed areas. Smaller changes in stream temperature are predicted for streams with high initial rates of heat loss associated with longwave radiation and evaporation, and greater base-flow index values. These models provide important insight into the potential extent of stream temperature warming at a near-continental scale and why some streams will likely be more vulnerable to climate change than others. Copyright Springer Science+Business Media Dordrecht 2014

Suggested Citation

  • Ryan Hill & Charles Hawkins & Jiming Jin, 2014. "Predicting thermal vulnerability of stream and river ecosystems to climate change," Climatic Change, Springer, vol. 125(3), pages 399-412, August.
    • Handle: RePEc:spr:climat:v:125:y:2014:i:3:p:399-412
    DOI: 10.1007/s10584-014-1174-4
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    References listed on IDEAS

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    1. Jiming Jin & Shih-Yu Wang & Robert Gillies, 2011. "An Improved Dynamical Downscaling for the Western United States," Chapters, in: Juan A. Blanco & Houshang Kheradmand (ed.), Climate Change - Research and Technology for Adaptation and Mitigation, IntechOpen.
    2. L. Mearns & S. Sain & L. Leung & M. Bukovsky & S. McGinnis & S. Biner & D. Caya & R. Arritt & W. Gutowski & E. Takle & M. Snyder & R. Jones & A. Nunes & S. Tucker & D. Herzmann & L. McDaniel & L. Sloa, 2013. "Climate change projections of the North American Regional Climate Change Assessment Program (NARCCAP)," Climatic Change, Springer, vol. 120(4), pages 965-975, October.
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    Cited by:

    1. Kevin C. Rose & Britta Bierwagen & Scott D. Bridgham & Daren M. Carlisle & Charles P. Hawkins & N. LeRoy Poff & Jordan S. Read & Jason R. Rohr & Jasmine E. Saros & Craig E. Williamson, 2023. "Indicators of the effects of climate change on freshwater ecosystems," Climatic Change, Springer, vol. 176(3), pages 1-20, March.
    2. Schuwirth, Nele & Borgwardt, Florian & Domisch, Sami & Friedrichs, Martin & Kattwinkel, Mira & Kneis, David & Kuemmerlen, Mathias & Langhans, Simone D. & Martínez-López, Javier & Vermeiren, Peter, 2019. "How to make ecological models useful for environmental management," Ecological Modelling, Elsevier, vol. 411(C).
    3. Stephen J. Dugdale & R. Allen Curry & André St-Hilaire & Samuel N. Andrews, 2018. "Impact of Future Climate Change on Water Temperature and Thermal Habitat for Keystone Fishes in the Lower Saint John River, Canada," Water Resources Management: An International Journal, Published for the European Water Resources Association (EWRA), Springer;European Water Resources Association (EWRA), vol. 32(15), pages 4853-4878, December.

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