Simulations of midlatitude frontal clouds by single-column and cloud-resolving models during the Atmospheric Radiation Measurement March 2000 cloud intensive operational period

Shaocheng Xie, Minghua H. Zhang, Mark Branson, Richard T. Cederwall, Anthony D. Del Genio, Zachary A. Eitzen, Steven J. Ghan, Sam F. Iacobellis, Karen L. Johnson, Marat Khairoutdinov, Stephen A. Klein, Steven K. Krueger, Wuyin Lin, Ulrike Lohmann, Mark A. Miller, David A. Randall, Richard C.J. Somerville, Yogesh C. Sud, Gregory K. Walker, Audrey WolfXiaoqing Wu, Kuan Man Xu, J. John Yio, Guang Zhang, Junhua Zhang

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59 Scopus citations

Abstract

This study quantitatively evaluates the overall performance of nine single-column models (SCMs) and four cloud-resolving models (CRMs) in simulating a strong midlatitude frontal cloud system taken from the spring 2000 Cloud Intensive Observational Period at the Atmospheric Radiation Measurement (ARM) Southern Great Plains site. The evaluation data are an analysis product of constrained variational analysis of the ARM observations and the cloud data collected from the ARM ground active remote sensors (i.e., cloud radar, lidar, and laser ceilometers) and satellite retrievals. Both the selected SCMs and CRMs can typically capture the bulk characteristics of the frontal system and the frontal precipitation. However, there are significant differences in detailed structures of the frontal clouds. Both CRMs and SCMs overestimate high thin cirrus clouds before the main frontal passage. During the passage of a front with strong upward motion, CRMs underestimate middle and low clouds while SCMs overestimate clouds at the levels above 765 hPa. All CRMs and some SCMs also underestimated the middle clouds after the frontal passage. There are also large differences in the model simulations of cloud condensates owing to differences in parameterizations; however, the differences among intercompared models are smaller in the CRMs than the SCMs. In general, the CRM-simulated cloud water and ice are comparable with observations, while most SCMs underestimated cloud water. SCMs show huge biases varying from large overestimates to equally large underestimates of cloud ice. Many of these model biases could be traced to the lack of subgrid-scale dynamical structure in the applied forcing fields and the lack of organized mesoscale hydrometeor advections. Other potential reasons for these model errors are also discussed in the paper.

Original languageEnglish
Pages (from-to)1-25
Number of pages25
JournalJournal of Geophysical Research: Biogeosciences
Volume110
Issue number15
DOIs
StatePublished - Aug 16 2005
Externally publishedYes

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