Temperature dependence of global precipitation extremes
Journal
Geophysical Research Letters
Journal Volume
36
Date Issued
2009
Author(s)
Abstract
Data from the Global Precipitation Climatology Project (GPCP) covering the period 1979-2007 are examined for changes of precipitation extremes as a function of global mean temperature by using a new method which focuses on interannual differences rather than time series. We find that the top 10% bin of precipitation intensity increases by about 95% for each degree Kelvin (K) increase in global mean temperature, while 30%-60% bins decrease by about 20% K-1. The global average precipitation intensity increases by about 23% K -1, substantially greater than the increase of about 7% K -1 in atmospheric water-holding capacity estimated by the Clausius-Clapeyron equation. The large increase of precipitation intensity is qualitatively consistent with die hypothesis that the precipitation intensity should increase by more than 7% K-1 because of the additional latent heat released from the increased moisture. Our results also provide an independent evidence in support for significant increases in the number and/or size of strong global tropical cyclones. However an ensemble of 17 latest generation climate models estimates an increase of only about 2% K-1 in precipitation intensity, about one order of magnitude smaller than our value, suggesting that the risk of extreme precipitation events due to global warming is substantially greater than that estimated by the climate models. Copyright 2009 by the American Geophysical Union.
SDGs
Other Subjects
Bins; Climatology; Global warming; Precipitation (meteorology); Time series; Atmospheric water; Clausius-Clapeyron equations; Climate model; Extreme precipitation; Global precipitation; Global precipitation climatology projects; Global-mean temperature; Interannual; Order of magnitude; Precipitation extremes; Precipitation intensity; Temperature dependence; Tropical cyclone; Risk perception; climate modeling; climatology; extreme event; global warming; hydrological response; precipitation intensity; temperature effect; tropical cyclone; water retention
Type
journal article