A Robust Multi-scale Modeling System for the Study of Cloud and Precipitation Processes for PMM 

Scientists Involved: Wei-Kuo Tao (PI), Xiaowen Li (Co-PI), Toshi Matsui (Co-PI), Stephen Lang (Co-PI), Di Wu (Co-I)

Objective. The proposed modeling effort will further study cloud and precipitation processes over many scales of motion, ranging from cloud microphysical processes up to the large-scale circulations that organize the growth and decay of precipitation systems. This proposal will use satellite products (i.e., TRMM, CloudSat, Aqua and GPM core and constellation satellites) as well as data from major field campaigns (i.e., CV3P, MC3E and GCPEx) to validate and improve the microphysical processes in numerical models for the NASA Precipitation Missions. 

Approach. 

• Utilize satellite/GV products to identify any weaknesses and/or strengths within the microphysical processes used in the cloud-resolving and regional-scale models and to improve their performance by resolving any deficiencies. 

• Conduct high-resolution (both horizontal and vertical) model simulations with improved microphysics and land surface model for a variety of different cloud and precipitation systems from different geographic locations [i.e., the Midlatitude Continental Convective Clouds Experiment (MC3E), Canadian CloudSA T/CALIPSO V alidation Project (C3VP), GPM Cold-season Precipitation Experiment (GCPEx) and two tropical oceanic sites (Tropical Warm Pool - International Cloud Experiment or TWP-ICE and ARM MJO Investigation Experiment/DYNAmics of the MJO or AMIE/DYNAMO)] using the improved microphysics with an emphasis on ice-phase and mixed-phase precipitation systems in high-latitudes.

• Couple the high-resolution model results with a satellite simulator to produce the cloud data (including hydrometeors and their size distributions) and cloud properties (including latent heating, eddy transport and radiation) needed to advance GPM algorithm development and validation.