Metadata only
Datum
2023-02-27Typ
- Journal Article
ETH Bibliographie
yes
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Abstract
Mesoscale convective systems (MCSs) are responsible for a majority of warm season flash flood events in the central U.S. Given their high impact, it is critical to understand how MCSs will change in a future climate. This study identifies eight flood-producing MCS cases of different archetypes and runs ensembles of 192 high-resolution historical and future simulations in order to analyze the range in future MCS rainfall and structural changes. Future area-average rainfall increases by 98% on average, with an 89%–111% range among ensemble members, while maximum rainfall increases by 31%, with a 24%–43% range. MCSs components are classified into deep convective cores (DCCs), wide convective cores (WCCs), and broad stratiform regions (BSRs) to understand how changes in these structures contribute to future rainfall changes. In a warmer climate, the number of DCCs increase on average by +30 (+5,545%), the average WCC area increases by 75%, and the average BSR area increases by 40%. The future rainfall increases are mainly due to increases in convective rainfall with large variability in rainfall from DCCs and less variability from WCCs. Despite their increase in size, BSR rainfall shows little increase. These rainfall and structural changes vary among MCS types, with back-building MCSs exhibiting the largest increases in future rainfall mainly due to increases in the number of DCCs and WCC area. Such information is critical to better understand the drivers of change in future MCS rainfall and improve prediction of future flood impacts. Mehr anzeigen
Publikationsstatus
publishedExterne Links
Zeitschrift / Serie
Journal of Geophysical Research: AtmospheresBand
Seiten / Artikelnummer
Verlag
American Geophysical UnionOrganisationseinheit
09844 - Prein, Andreas Franz / Prein, Andreas Franz
ETH Bibliographie
yes
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