Understanding the Microphysical Control and Spatial-Temporal Variability of Warm Rain Probability Using CloudSat and MODIS Observations

Zhibo Zhang; Lazaros Oreopoulos; Matthew D Lebsock; David B Mechem; Justin Covert

doi:10.1029/2022GL098863

Understanding the Microphysical Control and Spatial-Temporal Variability of Warm Rain Probability Using CloudSat and MODIS Observations

Geophys Res Lett. 2022 May 28;49(10):e2022GL098863. doi: 10.1029/2022GL098863. Epub 2022 May 24.

Authors

Zhibo Zhang^{1

2}, Lazaros Oreopoulos³, Matthew D Lebsock⁴, David B Mechem⁵, Justin Covert⁵

Affiliations

¹ Physics Department UMBC Baltimore MD USA.
² Goddard Earth Sciences Technology and Research II UMBC Baltimore MD USA.
³ Climate and Radiation Laboratory NASA Goddard Space Flight Center Greenbelt MD USA.
⁴ Jet Propulsion Laboratory California Institute of Technology Pasadena CA USA.
⁵ Department of Geography & Atmospheric Science University of Kansas Lawrence KS USA.

Abstract

By combining measurements from MODIS and the CloudSat radar, we develop a parameterization scheme to quantify the combined microphysical controls by liquid water path (LWP) and cloud droplet number concentration (CDNC) of the probability of precipitation (PoP) in marine low cloud over tropical oceans. We demonstrate that the spatial-temporal variation of grid-mean in-cloud <PoP> can be largely explained by the variation of the joint probability density function of LWP and CDNC in the phase space specified by the bivariate PoP (LWP and CDNC) function. Through a series of sensitivity tests guided by this understanding, we find that in the Southeastern Pacific and Atlantic the stratocumulus to cumulus transition of the <PoP> is mainly due to the variation of CDNC while the annual cycle is mainly due to the variation of LWP. The results of this study provide a viable way to diagnose the root cause of warm rain problems in global climate models.

Keywords: CloudSat; MODIS; probability of precipitation; warm rain.