A Double‐Moment SBU‐YLIN Cloud Microphysics Scheme and Its Impact on a Squall Line Simulation

Xi Zhao; Yanluan Lin; Yali Luo; Qifeng Qian; Xi Liu; Xiantong Liu; Brian A. Colle

doi:10.1029/2021MS002545

Journal of Advances in Modeling Earth Systems (Nov 2021)

A Double‐Moment SBU‐YLIN Cloud Microphysics Scheme and Its Impact on a Squall Line Simulation

Xi Zhao,
Yanluan Lin,
Yali Luo,
Qifeng Qian,
Xi Liu,
Xiantong Liu,
Brian A. Colle

Affiliations

Xi Zhao: Ministry of Education Key Laboratory for Earth System Modeling Department of Earth System Science Institute for Global Change Studies Tsinghua University Beijing China
Yanluan Lin: Ministry of Education Key Laboratory for Earth System Modeling Department of Earth System Science Institute for Global Change Studies Tsinghua University Beijing China
Yali Luo: State Key Laboratory of Severe Weather Chinese Academy of Meteorological Science Beijing China
Qifeng Qian: Zhejiang Institute of Meteorological Sciences (Chinese Academy of Meteorological Sciences, Zhejiang Branch) Hangzhou China
Xi Liu: Nanjing Joint Institute for Atmospheric Sciences Nanjing China
Xiantong Liu: Institute of Tropical and Marine Meteorology CMA Guangzhou China
Brian A. Colle: School of Marine and Atmospheric Sciences Stony Brook University State University of New York Stony Brook NY USA

DOI: https://doi.org/10.1029/2021MS002545
Journal volume & issue: Vol. 13, no. 11
pp. n/a – n/a

Abstract

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Abstract A double‐moment version of the SBU‐YLIN cloud microphysical scheme in WRF is introduced. It predicts the mass and number mixing ratios of cloud droplet, rain, cloud ice, and precipitating ice. In addition, a number of physical processes, like rain evaporation, collection between rain and snow are also optimized in the new scheme. The scheme is evaluated and compared with the original one‐moment scheme for a squall line case. We found that the double‐moment approach gives a better representation of rain evaporation, which is critical for the development, morphology, and evolution of the simulated squall line, especially for the enhanced trailing stratiform cloud and leading convective line. The relationship between key microphysical processes and squall line dynamics is investigated to identify the driving mechanisms of the descending rear inflow, cold pool, and slantwise updraft. Furthermore, formation of the transition zone in the simulated squall line strongly depends on the flexible description of ice particle properties, such as size, degree of riming and fall speed.

Published in Journal of Advances in Modeling Earth Systems

ISSN: 1942-2466 (Online)
Publisher: American Geophysical Union (AGU)
Country of publisher: United States
LCC subjects: Geography. Anthropology. Recreation: Physical geography; Geography. Anthropology. Recreation: Oceanography
Website: https://agupubs.onlinelibrary.wiley.com/journal/19422466

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