Condensation–mass flux connection in warm convective clouds: theory and implications for cloud supersaturation

Q2 Earth and Planetary Sciences

Advances in Science and Research Pub Date : 2022-08-22 DOI:10.5194/asr-19-91-2022

Y. Kogan

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Abstract

Abstract. The study focused on the relationship between Condensation Rate (CR) and the upward/Plus Mass Flux (MFP) in a system of trade wind cumulus clouds simulated by an LES model. The model was initialized with data observed during the RICO field project, and simulated in a 50.0×50.0 km horizontal domain. In our previous study (Kogan, 2021) we showed that a nearly perfect correlation exists between CR and MFP (correlation coefficient R=0.99). As a result, condensation rate can be highly accurately expressed as a linear function of upward mass flux. This LES derived finding was explained using condensation theory and concept of quasi-steady supersaturation. The obtained from the LES model slope of the CR–MFP linear fit was in excellent agreement with its theoretical value (error less than 5 %). The theory also showed that the equality between the LES and theoretical values of the slope follows from the equality between supersaturation and its quasi-steady value. The study results suggest that condensation rates, for a variety of cloud conditions, can be precisely estimated using the single variable–upward mass flux. Possible implications of the results for evaluating supersaturation and degree of non-adiabaticity in clouds are discussed.

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暖对流云中凝聚-质量通量的联系:云过饱和的理论和意义

摘要研究了LES模式模拟的信风积云系统中凝结速率(CR)与上升/上升质量通量(MFP)的关系。模型初始化采用RICO野外项目观测数据，并在50.0×50.0 km水平域内进行模拟。在我们之前的研究(Kogan, 2021)中，我们发现CR和MFP之间存在近乎完美的相关性(相关系数R=0.99)。因此，冷凝率可以非常精确地表示为向上质量通量的线性函数。用缩合理论和准稳定过饱和的概念解释了这一LES导出的发现。由LES模型得到的CR-MFP线性拟合斜率与其理论值吻合良好(误差小于5%)。该理论还表明，从过饱和度与其准稳态值相等出发，LES值与斜率理论值相等。研究结果表明，对于各种云条件下的凝结速率，可以使用单变量向上的质量通量来精确估计。讨论了这些结果对评估云中的过饱和度和非绝热度可能产生的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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