The Changing Influence of Precipitation on Soil Moisture Drought With Warming in the Mediterranean and Western North America

Nielsen, Miriam; Cook, Benjamin I.; Marvel, Kate; Ting, Mingfang; Smerdon, Jason E.

doi:10.1029/2023EF003987

Title: The Changing Influence of Precipitation on Soil Moisture Drought With Warming in the Mediterranean and Western North America

Journal Article · 13 May 2024 · Earth's Future

DOI: https://doi.org/10.1029/2023EF003987 · OSTI ID:2349561

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NASA Goddard Institute for Space Studies New York NY USA, Department of Earth and Environmental Science Columbia University New York NY USA
NASA Goddard Institute for Space Studies New York NY USA, Lamont‐Doherty Earth Observatory Columbia University Palisades NY USA
NASA Goddard Institute for Space Studies New York NY USA, Project Drawdown St. Paul MN USA
Columbia Climate School Columbia University New York NY USA

Abstract Anthropogenic climate change has already affected drought severity and risk across many regions, and climate models project additional increases in drought risk with future warming. Historically, droughts are typically caused by periods of below‐normal precipitation and terminated by average or above‐normal precipitation. In many regions, however, soil moisture is projected to decrease primarily through warming‐driven increases in evaporative demand, potentially affecting the ability of negative precipitation anomalies to cause drought and positive precipitation anomalies to terminate drought. Here, we use climate model simulations from Phase Six of the Coupled Model Intercomparison Project (CMIP6) to investigate how different levels of warming (1, 2, and 3°C) affect the influence of precipitation on soil moisture drought in the Mediterranean and Western North America regions. We demonstrate that the same monthly precipitation deficits (25th percentile relative to a preindustrial baseline) at a global warming level of 2°C increase the probability of both surface and rootzone soil moisture drought by 29% in the Mediterranean and 32% and 6% in Western North America compared to the preindustrial baseline. Furthermore, the probability of a dry (25th percentile relative to a preindustrial baseline) surface soil moisture month given a high (75th percentile relative to a preindustrial baseline) precipitation month is 6 (Mediterranean) and 3 (Western North America) times more likely in a 2°C world compared to the preindustrial baseline. For these regions, warming will likely increase the risk of soil moisture drought during low precipitation periods while simultaneously reducing the efficacy of high precipitation periods to terminate droughts.

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Sponsoring Organization:: USDOE

Grant/Contract Number:: ESC0022302

OSTI ID:: 2349561

Journal Information:: Earth's Future, Journal Name: Earth's Future Vol. 12 Journal Issue: 5; ISSN 2328-4277

Publisher:: American Geophysical Union (AGU)Copyright Statement

Country of Publication:: United States

Language:: English

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