摘要 : This research seeks to understand simulated supercell precipitation characteristics across the conterminous United States (CONUS) using high-resolution, convection-permitting, dynamically downscaled simulations for three 15-year e... 展开 This research seeks to understand simulated supercell precipitation characteristics across the conterminous United States (CONUS) using high-resolution, convection-permitting, dynamically downscaled simulations for three 15-year epochs. Epochs include a historical end-of-20th-century period (1990-2005) and two end-of-21st-century (2085-2100) scenarios for intermediate and pessimistic greenhouse gas concentration trajectories. Simulated updraft helicity, which measures the corkscrew flow within a storm's updraft, is used as a proxy for supercells. An algorithm tracks and catalogues updraft helicity swaths that, when buffered, are used to acquire simulated precipitation from supercells. The historical epoch provides a baseline climatology of supercell precipitation for a contemporary climate, which is then compared against the two future epochs to assess how supercell precipitation may change during the 21st century. Despite their relatively small size, supercells provide critical precipitation to the Wheat and Corn Belts, large expanses of CONUS pasture and rangeland, regional aquifers and several large river basins. Many areas in the central CONUS receive upwards of 3%-6% of their annual and 5%-8% of their warm-season precipitation from these storms. Results suggest that precipitation contribution from supercells will decrease in the future across most of the High Plains and Central and Northern Great Plains with robust increases likely across the south-central and Southeast regions. Supercell precipitation rates are expected to increase for large portions of the CONUS by the end-of-the-21st-century, suggesting a growing threat for flash floods from these storms as they become more efficient precipitation producers. This research provides an initial perspective on the magnitude of supercell precipitation and potential changes to this important hydrologic input to assist water-sensitive industries, private and public insurance markets, agriculture entities, as well as inform plans to mitigate and build resilience to rapid environmental and societal change.This research illustrates the precipitation contributions to the United States hydroclimate from rotating thunderstorms known as supercells and how those contributions will change in the 21st century. Results will assist water-sensitive industries, insurance markets and agriculture entities to mitigate and build resilience to rapid environmental and societal changes. image 收起