Precipitation responses to radiative processes of water- and ice-clouds: an equilibrium cloud-resolving modeling study 被引量：3

Precipitation responses to radiative processes of water- and ice-clouds: an equilibrium cloud-resolving modeling study

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摘要 Cloud radiative processes are important in regulating weather and climate. Precipitation responses to radiative processes of water- and ice-clouds are investigated by analyzing mean equilibrium simulation data from a series of two-dimensional cloud-resolving model sensitivity experiments in this study. The model is imposed by zero vertical velocity.The exclusion of water radiative processes in the presence of ice radiative processes, as well as the removal of ice radiative processes, enhances tropospheric Iongwave radiative cooling and lowers air temperature and the saturation mixing ratio. The reduction in the saturation mixing ratio leads to an increase in vapor condensation and an associated release of latent heat, which increases rainfall. The elimination of water radiative processes strengthens local atmospheric warming Iongwave radiative cooling. The enhanced warming melting of graupel, which increases rainfa n the upper troposphere via a reduction in ncreases the rain source via an increase in the 云辐射过程对制约天气与气候很重要。本文通过分析二维云分辨模式敏感性试验模拟平衡态平均资料研究降水对水云及冰云辐射过程的响应。模式给定的垂直速度为零。存在冰云辐射过程时去除水云辐射过程,以及去除冰云辐射过程会加强大气长波辐射冷却和降低空气温度及饱和混合比。饱和混合比的减少导致水汽凝结增加及其相关的潜热释放的增加,从而增加降雨。去除水云辐射过程通过减少长波辐射冷却增加对流层上部局地大气变暖。而增强的变暖通过霰的融化增强而增加降水源与降水。

作者 XIN Jin LI Xiao-Fan

机构地区 School of Earth Sciences

出处《Atmospheric and Oceanic Science Letters》 CSCD 2016年第4期306-314,共9页 大气和海洋科学快报（英文版）

基金 supported by the National Natural Science Foundation of China[grant number 41475039] the National Basic Research Program of China[grant number 2015CB953601]

关键词 Radiative processes water-cloud ice-cloud PRECIPITATION longwaveradiative cooling equilibriumcloud-resolving modelsimulation 辐射过程水云冰云降水长波辐射冷却云分辨模式平衡态模拟

分类号 P426 [天文地球—大气科学及气象学]

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参考文献3

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2016年第4期

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