Comparing and Blending Regional Climate Model Predictions for the American Southwest |
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Authors: | Esther Salazar Bruno Sansó Andrew O Finley Dorit Hammerling Ingelin Steinsland Xia Wang Paul Delamater |
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Institution: | 1.Department of Electrical and Computer Engineering,Duke University,Durham,USA;2.Department of Applied Mathematics and Statistics,University of California Santa Cruz,Santa Cruz,USA;3.Departments of Forestry and Geography,Michigan State University,East Lansing,USA;4.Department of Environmental Engineering,University of Michigan,Ann Arbor,USA;5.Department of Mathematical Sciences,Norwegian University of Science and Technology,Trondheim,Norway;6.Department of Mathematical Sciences,University of Cincinnati,Cincinnati,USA;7.Department of Geography,Michigan State University,East Lansing,USA |
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Abstract: | We consider the problem of forecasting future regional climate. Our method is based on blending different members of an ensemble
of regional climate model (RCM) simulations while accounting for the discrepancies between these simulations, under present
day conditions, and observational records for the recent past. To this end, we develop Bayesian space-time models that assess
the discrepancies between climate model simulations and observational records. Those discrepancies are then propagated into
the future to obtain blended forecasts of 21st century climate. The model allows for location-dependent spatial heterogeneities,
providing local comparisons between the different simulations. Additionally, we estimate the different modes of spatial variability,
and use the climate model-specific coefficients of the spatial factors for comparisons. We focus on regional climate model
simulations performed in the context of the North American Regional Climate Change Assessment Program (NARCCAP). We consider,
in particular, simulations from RegCM3 using three different forcings: NCEP, GFDL and CGCM3. We use simulations for two time
periods: current climate conditions, covering 1971 to 2000, and future climate conditions under the SRES A2 emissions scenario,
covering 2041 to 2070. We investigate yearly mean summer temperature for a domain in the South West of the United States.
The results indicated the RCM simulations underestimate the mean summer temperature increase for most of the domain compared
to our model. |
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