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Extreme Precipitation‐Temperature Scaling in California: The Role of Atmospheric Rivers

Nasser Najibi, Scott Steinschneider

2023Geophysical Research Letters21 citationsDOIOpen Access PDF

Abstract

Abstract The sensitivity of atmospheric river (AR)‐induced precipitation to climate change is primarily driven by increases in atmospheric water vapor with warming. However, the rate at which AR‐based precipitation intensifies with warming and whether this rate differs from non‐AR events remains uncertain. This work uses multiple statistical models to estimate regional, extreme precipitation‐temperature scaling rates in California for AR and non‐AR events. Scaling rates are determined using cold‐season daily and hourly precipitation, along with multiple temperature variables to assess robustness of the results. We find that regional scaling rates for ARs are consistently larger than non‐ARs, especially for hourly event maxima (posterior median scale rates of 5.7% and 2.4% per °C for ARs and non‐ARs, respectively). ARs remain near saturated (i.e., high relative humidity) and exhibit more lift and a stronger increase in specific humidity aloft with warming as compared to non‐ARs, helping to explain the difference in precipitation‐temperature scaling rates.

Topics & Concepts

Environmental sciencePrecipitationScalingAtmospheric sciencesRelative humidityClimatologyWater vaporClimate changeHumidityLapse rateMeteorologyGeologyGeographyGeometryOceanographyMathematicsClimate variability and modelsHydrology and Watershed Management StudiesFlood Risk Assessment and Management
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