Changing Tropical Extreme Rainfall Characteristics in Warmer Climates
In this paper, we examine the changing characters of extreme tropical precipitation based on simulations with of the Department of Energy (DOE), Exascale Energy Earth System Model (E3SM). AMIP-type experiments were carried out respectively for control (present-day SST and CO2), P4K (+4K uniform SSTA, with present-day CO2), and 4XCO2 (quadruple CO2 atmospheric forcing, and matching SSTA, based on CMIP6 ensemble coupled model projections). Top 5% (PCT05) and 1% (PCT01) rain intensity in the control are used as a metric to define extreme precipitation.
Results show significant increase in both convective precipitation (CVP) and stratiform precipitation (STP) as a function of rainfall intensity, with the STP increasing much more than CVP for extreme precipitation. Under P4K, and 4xCO2 respectively, the tropical warm pool (SST> 29oC) expands substantially, covering nearly the entire tropics. Increase in extreme precipitation generally follows the paradigm of “wet-getting-wetter” and “warmer-getting-wetter”. PCT05 and PCT01 heavy rainfall are associated with strong radiation-cloud-convection-circulation interaction (R3CI), with increased contribution from STP. Four extreme precipitation regimes are identified:
- Open ocean: Increase in relative humidity (RH) near surface and lower-troposphere lead to increase in rainfall efficiency, i.e., more PCT05, PCT01 rainfall from warmer clouds (lower cloud top) over the ITCZ/SPCZ core, and expanded region with warmer SST (exceeding 29o C) under P4K and 4xCO2.
- Continental land: Strong surface warming, reduction in surface RH, but with strong upper-level heating by LS precipitation, over the equatorial Africa, and the Amazon
- Maritime continent: Mixed behavior from ocean and continental land, including emerging signals of fixed anvil temperature (FAT) associated with extreme precipitation
- Asian monsoon region: By far, this region shows the strongest signal of increased contribution by STP and FAT, stronger in 4xCO2 then P4K, indicating importance of atmospheric heating by CO2 in amplifying effects of land-sea surface heating contrast.