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Simulation of the Microphysical Processes and Effect of Latent Heat on a Heavy Rainfall Event in Beijing

Simulation of the Microphysical Processes and Effect of Latent Heat on a Heavy Rainfall Event in Beijing
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摘要 An extraordinary rainstorm that occurred in Beijing on 21 July 2012 was simulated using the Weather Research and Forecasting model. The results showed that:(1) The two precipitation phases were based on a combination of cold cloud processes and warm cloud processes. The accumulated conversion amount and conversion rate of microphysical processes in the warm-area phase were all much larger than those in the cold front phase.(2) 72.6% of rainwater was from the warm-area phase. Rainwater mainly came from the melting of graupel and the melting of snow, while the accretion of cloud water by rain ranked second.(3) The net heating rate with height appeared as an overall warming with two strong heating centers in the lower and middle layers of the troposphere and a minimum heating center around the melting layer. The net heating effect in the warm-area phase was stronger than that in the cold front phase.(4) Warm cloud processes contributed most to latent heat release, and the thermal effect of cold cloud processes on the storm in the cold front phase was enhanced compared to that in the warm-area phase.(5) The melting of graupel and snow contributed most to latent heat absorption, and the effect of the evaporation of rainwater was significantly reduced in the cold front phase. An extraordinary rainstorm that occurred in Beijing on 21 July 2012 was simulated using the Weather Research and Forecasting model. The results showed that:(1) The two precipitation phases were based on a combination of cold cloud processes and warm cloud processes. The accumulated conversion amount and conversion rate of microphysical processes in the warm-area phase were all much larger than those in the cold front phase.(2) 72.6% of rainwater was from the warm-area phase. Rainwater mainly came from the melting of graupel and the melting of snow, while the accretion of cloud water by rain ranked second.(3) The net heating rate with height appeared as an overall warming with two strong heating centers in the lower and middle layers of the troposphere and a minimum heating center around the melting layer. The net heating effect in the warm-area phase was stronger than that in the cold front phase.(4) Warm cloud processes contributed most to latent heat release, and the thermal effect of cold cloud processes on the storm in the cold front phase was enhanced compared to that in the warm-area phase.(5) The melting of graupel and snow contributed most to latent heat absorption, and the effect of the evaporation of rainwater was significantly reduced in the cold front phase.
出处 《Atmospheric and Oceanic Science Letters》 CSCD 2014年第6期521-526,共6页 大气和海洋科学快报(英文版)
基金 supported by the National Basic Research Program of China (973 Program, Grant Nos. 2013CB430105 and 2014CB441403) the National Natural Science Foundation of China (Grant No. 41205099) Guizhou Province Scientific Research Joint Project (Grant No. G[2013]4001) the Special Scientific Research Project of Meteorological Public Welfare Profession of China (Grant No. GYHY201006031)
关键词 extraordinary rainstorm warm-area precipitation cold front precipitation microphysical processes latent heat effect 微物理过程 潜热释放 北京 暴雨 模拟 事件 加热速率 预报模型
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