Litcius/Paper detail

Projected Changes to Extreme Runoff and Precipitation Events From a Downscaled Simulation Over the Western United States

Melissa L. Wrzesien, Tamlin M. Pavelsky

2020Frontiers in Earth Science30 citationsDOIOpen Access PDF

Abstract

Extreme precipitation and runoff events, which often impact natural and social systems more than mean changes, generally occur over regional scales. Future climate projections can be used to estimate how the hydrologic cycle may change, but the coarse resolution of global climate models (>1°) makes it difficult to evaluate regional changes, such as over a single watershed. To estimate changes in hydroclimatic variables at finer spatial resolutions, we dynamically downscale the Community Earth System Model (CESM) with the Weather Research and Forecasting (WRF) regional climate model over the western United States at 9 km spatial resolution. By running WRF at a higher spatial resolution, we estimate future climate conditions, including 99% and 99.9% event magnitude, over seventeen watersheds: the Columbia, Lower Colorado, Upper Colorado, the Upper Missouri/Yellowstone, and twelve basins draining the western slope of the Sierra Nevada in California. Over each basin, we compare a historical period (1996-2005) with mid-century (2041-2050) and end-century (2091-2100). From the WRF/CESM simulations, most basins are projected to have earlier peaks in springtime streamflow. The Columbia and the Lower Colorado watersheds are both expected to experience more extreme wet days, with the 99th percentile of daily precipitation estimated to increase by over 10%. For the Upper Colorado, however, the 99th percentile of daily runoff is projected to decrease by over 30%. Basins in the northern and central Sierra Nevada are projected to have substantial increases in extreme runoff, with doubling of high flow event magnitude possible for some basins. By end-century, the contribution of high-magnitude runoff (>90th percentile) to total runoff is projected to increase from 46% to 56%, when averaged across all twelve Sierra Nevada basins. Though only one realization from a single global climate model, the downscaled simulation presented here shows interesting results regarding how extreme events may change; these results can be tested by downscaling other global models with WRF to create an ensemble of dynamically downscaled future projections.

Topics & Concepts

Weather Research and Forecasting ModelPrecipitationClimatologySurface runoffEnvironmental scienceClimate modelStreamflowClimate changeStructural basinWatershedDrainage basinDownscalingWater cycleHydrology (agriculture)GeologyGeographyMeteorologyEcologyOceanographyBiologyCartographyPaleontologyMachine learningGeotechnical engineeringComputer scienceClimate variability and modelsHydrology and Watershed Management StudiesMeteorological Phenomena and Simulations