Long-Term Regional Hydroclimate Modeling for Communities and Decision-Makers across Alaska and Northwestern Canada
Modélisation hydroclimatique régionale à long terme pour les communautés et les décideurs de l'Alaska et du Nord-Ouest canadien
Newman, Andrew J. ; Cheng, Yifan ; Blaskey, Dylan ; Herman-Mercer, Nicole M. ; Craig, Anthony P. ; Koch, Joshua ; Toohey, Ryan ; Mutter, Edda ; Carey, Michael P. ; Gooseff, Michael N. ; Swanson, Heidi ; Thomas, Peyton ; Brooks, Cassandra ; Musselman, Keith N.
Année de publication
2026
A novel, high-resolution land-atmosphere regional climate model (RCM) configuration for Alaska and northwestern Canada is presented. Key model decisions were informed by Indigenous survey respondents who improved model and data usefulness and usability. First, to enable climate change assessments at Arctic community scales, the Regional Arctic System Model (RASM) was modified from its 50-km grid spacing to 4 km. Next, to advance RASM land modeling, the Community Terrestrial Systems Model (CTSM) was coupled to RASM with hydrology-specific optimization; this was a novel effort for coupled land-atmosphere RCM streamflow performance. The resultant configuration, forced by ERA5 reanalysis, has resulted in high-quality simulations of the historical hydroclimate [water year (WY1990-2021)]. An ensemble of six future simulations for the mid-twenty-first century, WY2035-2065, was then developed using two approaches that address community needs for a range of plausible futures to inform decision-making. The two future climate simulation approaches were 1) the pseudo-global warming (PGW) method, using two deltas applied to historical weather, and 2) direct downscaling of four CESM2 Large Ensemble members. Overall, the unique RASM model was used to produce 330 simulation years intended for use within interdisciplinary climate change research and which serve Arctic community needs. Highlighted features include the codesign process, model developments, dataset characteristics, and examples of projected future regional hydrometeorological change across the future ensemble including contrasts between the PGW and direct downscaled futures. Significance Statement Codesign and integrated community involvement are critical to reduce barriers to use and improve the usefulness and usability of highly technical climate models and data. Here, we synthesize our process to codesign a regional climate model configuration and subsequent dataset development, along with our evaluation processes. Our simulations cover the recent historical hydroclimate along with experiments of mid-twenty-first century change based on codesign. Our results show that significant mid-twenty-first century changes are likely to occur across a range of temperature, precipitation, and river conditions and will include substantial increases in the maximum annual daily air temperature, precipitation, and streamflow.</div>
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