Impacts of 21st‐Century Climate Change on Hydrologic Extremes in the Pacific Northwest Region of North America |
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Authors: | Ingrid M. Tohver Alan F. Hamlet Se‐Yeun Lee |
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Affiliation: | 1. Climate Impacts Group, University of Washington, , Seattle, Washington, 98195Paper No. JAWRA‐13‐0050‐P of the Journal of the American Water Resources Association (JAWRA).;2. Climate Impacts Group, University of Washington, , Seattle, Washington, 98195;3. Department of Civil and Environmental Engineering and Earth Sciences, University of Notre Dame, , Notre Dame, Indiana, 46556;4. School of Environmental and Forest Sciences, University of Washington, , Seattle, Washington, 98195 |
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Abstract: | Climate change projections for the Pacific Northwest (PNW) region of North America include warmer temperatures (T), reduced precipitation (P) in summer months, and increased P during all other seasons. Using a physically based hydrologic model and an ensemble of statistically downscaled global climate model scenarios produced by the Columbia Basin Climate Change Scenarios Project, we examine the nature of changing hydrologic extremes (floods and low flows) under natural conditions for about 300 river locations in the PNW. The combination of warming, and shifts in seasonal P regimes, results in increased flooding and more intense low flows for most of the basins in the PNW. Flood responses depend on average midwinter T and basin type. Mixed rain and snow basins, with average winter temperatures near freezing, typically show the largest increases in flood risk because of the combined effects of warming (increasing contributing basin area) and more winter P. Decreases in low flows are driven by loss of snowpack, drier summers, and increasing evapotranspiration in the simulations. Energy‐limited basins on the west side of the Cascades show the strongest declines in low flows, whereas more arid, water‐limited basins on the east side of the Cascades show smaller reductions in low flows. A fine‐scale analysis of hydrologic extremes over the Olympic Peninsula echoes the results for the larger rivers discussed above, but provides additional detail about topographic gradients. |
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Keywords: | Columbia River basin hydrologic extremes flood low flow climate change downscaled global climate models hydrologic models |
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