Estimates of Twenty-First-Century Flood Risk in the Pacific Northwest Based on Regional Climate Model Simulations

Results from a regional climate model simulation show substantial increases in future flood risk (2040–69) in many Pacific Northwest river basins in the early fall. Two primary causes are identified: 1) more extreme and earlier storms and 2) warming temperatures that shift precipitation from snow to...

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Published in:Journal of hydrometeorology 2014-10, Vol.15 (5), p.1881-1899
Main Authors: Salathé, Eric P., Hamlet, Alan F., Mass, Clifford F., Lee, Se-Yeun, Stumbaugh, Matt, Steed, Richard
Format: Article
Language:English
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Atmospheric models
Climate change
Climate models
Floods
Hydrological modeling
Modeling
Precipitation
Simulations
Storms
Stream flow
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container_end_page 1899
container_issue 5
container_start_page 1881
container_title Journal of hydrometeorology
container_volume 15
creator Salathé, Eric P.
Hamlet, Alan F.
Mass, Clifford F.
Lee, Se-Yeun
Stumbaugh, Matt
Steed, Richard
description Results from a regional climate model simulation show substantial increases in future flood risk (2040–69) in many Pacific Northwest river basins in the early fall. Two primary causes are identified: 1) more extreme and earlier storms and 2) warming temperatures that shift precipitation from snow to rain dominance over regional terrain. The simulations also show a wide range of uncertainty among different basins stemming from localized storm characteristics. While previous research using statistical downscaling suggests that many areas in the Pacific Northwest are likely to experience substantial increases in flooding in response to global climate change, these initial estimates do not adequately represent the effects of changes in heavy precipitation. Unlike statistical downscaling techniques applied to global climate model scenarios, the regional model provides an explicit, physically based simulation of the seasonality, size, location, and intensity of historical and future extreme storms, including atmospheric rivers. This paper presents climate projections from the ECHAM5/Max Planck Institute Ocean Model (MPI-OM) global climate model dynamically downscaled using the Weather Research and Forecasting (WRF) Model implemented at 12-km resolution for the period 1970–2069. The resulting daily precipitation and temperature data are bias corrected and used as input to a physically based Variable Infiltration Capacity (VIC) hydrologic model. From the daily time step simulations of streamflow produced by the hydrologic model, probability distributions are fit to the extreme events extracted from each water year and flood statistics for various return intervals are estimated.
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subjects Atmospheric models
Climate change
Climate models
Floods
Hydrological modeling
Modeling
Precipitation
Simulations
Storms
Stream flow
title Estimates of Twenty-First-Century Flood Risk in the Pacific Northwest Based on Regional Climate Model Simulations
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