H12E-01
Evaluating Cloud and Precipitation Processes in Numerical Models using Current and Potential Future Satellite Missions

Monday, 14 December 2015: 10:20
3022 (Moscone West)
Susan C van den Heever1, Wei-Kuo Tao2, Gail Skofronick Jackson2, Simone Tanelli3, Tristan S L'Ecuyer4, Walter Arthur Petersen2 and Christian D Kummerow5, (1)Colorado State University, Atmospheric Science, Fort Collins, CO, United States, (2)NASA Goddard Space Flight Center, Greenbelt, MD, United States, (3)Jet Propulsion Laboratory, Pasadena, CA, United States, (4)University of Wisconsin Madison, Madison, WI, United States, (5)Colorado State Univ, Fort Collins, CO, United States
Abstract:
Cloud, aerosol and precipitation processes play a fundamental role in the water and energy cycle. It is critical to accurately represent these microphysical processes in numerical models if we are to better predict cloud and precipitation properties on weather through climate timescales. Much has been learned about cloud properties and precipitation characteristics from NASA satellite missions such as TRMM, CloudSat, and more recently GPM. Furthermore, data from these missions have been successfully utilized in evaluating the microphysical schemes in cloud-resolving models (CRMs) and global models. However, there are still many uncertainties associated with these microphysics schemes. These uncertainties can be attributed, at least in part, to the fact that microphysical processes cannot be directly observed or measured, but instead have to be inferred from those cloud properties that can be measured. Evaluation of microphysical parameterizations are becoming increasingly important as enhanced computational capabilities are facilitating the use of more sophisticated schemes in CRMs, and as future global models are being run on what has traditionally been regarded as cloud-resolving scales using CRM microphysical schemes.

In this talk we will demonstrate how TRMM, CloudSat and GPM data have been used to evaluate different aspects of current CRM microphysical schemes, providing examples of where these approaches have been successful. We will also highlight CRM microphysical processes that have not been well evaluated and suggest approaches for addressing such issues. Finally, we will introduce a potential NASA satellite mission, the Cloud and Precipitation Processes Mission (CAPPM), which would facilitate the development and evaluation of different microphysical-dynamical feedbacks in numerical models.