Modeling study of the effects of entrainment-mixing on fog simulation in the chemistry–weather coupling model GRAPES_Meso5.1/CUACE CW

IF 2.8 Q3 ENVIRONMENTAL SCIENCES Environmental science: atmospheres Pub Date : 2024-02-19 DOI:10.1039/D4EA00003J
Yang Zhao, Hong Wang, Xiaoqi Xu, Wenjie Zhang, Chen Han, Yue Peng and Chunsong Lu
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Abstract

Entrainment-mixing processes of fog with the surrounding ambient air are extremely intricate and impose significant effects on the microphysical and radiative properties of fog. However, it is difficult to utilize the default Thompson scheme of the atmospheric chemistry model GRAPES_Meso5.1/CUACE to examine the effects of different entrainment-mixing mechanisms on the microphysical and radiative properties of fog. To address this issue, this scheme is modified to include homogeneous mixing degree to investigate the effects of various entrainment-mixing processes on typical regional fog simultaneously occurring in the Northeast China and Yangtze River Delta regions from December 31, 2016, to January 2, 2017, and from January 6 to 8, 2017. It is revealed that inhomogeneous entrainment-mixing processes can result in smaller fog droplet number concentration and lower liquid water path, and larger fog droplet size. These phenomena, in turn, can lead to a decreased fog optical thickness and increased visibility. Furthermore, the effects of inhomogeneous entrainment-mixing processes depend on fog thickness, i.e., the effects in thin fog in the Northeast China region are more significant than those in thick fog in the Yangtze River Delta region. This primarily occurs because the proportion of evaporated grids in thin fog is higher than that in thick fog by 16% and 6%, respectively. These findings enhance the theoretical understanding of entrainment-mixing processes and lay the foundation for improving model parameterization.

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化学-天气耦合模型 GRAPES_Meso5.1/CUACE CW 中夹带混合对雾模拟影响的模型研究
雾与周围环境空气的夹带混合过程极其复杂,对雾的微观物理和辐射特性有重大影响。然而,很难利用大气化学模型 GRAPES_Meso5.1/CUACE 的默认汤普森方案来研究不同夹带混合机制对雾的微物理和辐射特性的影响。针对这一问题,对该方案进行了修改,加入了均质混合程度,研究了2016年12月31日至2017年1月2日以及2017年1月6日至8日同时发生在中国东北地区和长三角地区的典型区域雾的各种夹带混合过程的影响。研究发现,非均质夹带混合过程会导致雾滴数量浓度变小、液态水路径变低,雾滴尺寸变大。这些现象反过来又会导致雾光学厚度减小,能见度增加。此外,不均匀夹带混合过程的影响取决于雾的厚度,即东北地区薄雾的影响比长江三角洲地区浓雾的影响更大。这主要是因为薄雾中蒸发网格的比例分别比浓雾中高 16% 和 6%。这些发现加深了对夹带混合过程的理论认识,为改进模型参数化奠定了基础。
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