A Simple Model for the Evaporation of Hydrometeors and Their Isotopes

IF 3.8 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Geophysical Research: Atmospheres Pub Date : 2024-11-20 DOI:10.1029/2024JD041126

Simon P. de Szoeke, Mampi Sarkar, Estefanía Quiñones Meléndez, Peter N. Blossey, David Noone

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引用次数: 0

Abstract

Cloud condensation and hydrometeor evaporation fractionate stable isotopes of water, enriching liquid with heavy isotopes; whereupon updrafts, downdrafts, and rain vertically redistribute water and its isotopes in the lower troposphere. These vertical water fluxes through the marine boundary layer affect low cloud climate feedback and, combined with isotope fractionation, are hypothesized to explain the depletion of tropical precipitation at higher precipitation rates known as the “amount effect.” Here, an efficient and numerically stable quasi-analytical model simulates the evaporation of raindrops and enrichment of their isotope composition. It is applied to a drop size distribution and subcloud environment representative of Atlantic trade cumulus clouds. Idealized physics experiments artificially zero out selected processes to discern the separate effects on the isotope ratio of raindrops, of exchange with the environment, evaporation, and kinetic molecular diffusion. A parameterization of size-dependent molecular and eddy diffusion is formulated that enriches raindrops much more strongly (+5‰ for deuterated water [HDO] and +3.5‰ for $H_{2}^{18}$ O) than equilibrium evaporation as they become smaller than 1 mm. The effect on evaporated vapor is also assessed. Rain evaporation enriches subcloud vapor by +12‰ per mm rain (for HDO), explaining observations of enriched vapor in cold pools sourced by evaporatively cooled downdrafts. Drops smaller than 0.5 mm evaporate completely before falling 700 m in typical subtropical marine boundary layer conditions. The early and complete evaporation of these smaller drops in the rain size distribution enriches the vapor produced by rain evaporation.

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水介质及其同位素蒸发的简单模型

云凝结和水流星蒸发会分馏出稳定的水同位素，使液体富含重同位素；随后上升气流、下降气流和降雨会在对流层低层垂直重新分配水及其同位素。这些通过海洋边界层的垂直水通量影响低云气候反馈，并与同位素分馏相结合，被假定为可以解释在较高降水率下热带降水的耗竭，即所谓的 "量效应"。在这里，一个高效且数值稳定的准分析模型模拟了雨滴的蒸发及其同位素组成的富集。该模型适用于代表大西洋贸易积云的雨滴大小分布和云下环境。理想化物理实验人为地将选定的过程归零，以辨别与环境交换、蒸发和分子动力学扩散对雨滴同位素比率的不同影响。制定了一个尺寸依赖性分子扩散和涡流扩散的参数化，当雨滴变得小于 1 毫米时，它比平衡蒸发富集得更强（氘化水 [HDO] 富集 +5‰，H 2 18 ${mathrm{H}}_{2}^{18}$ O 富集 +3.5‰）。还评估了对蒸发水汽的影响。雨水蒸发使云下水汽富集，每毫米雨水富集+12‰（HDO），这解释了在由蒸发冷却的下沉气流形成的冷池中观测到的富集水汽。在典型的亚热带海洋边界层条件下，小于 0.5 毫米的雨滴在下降 700 米之前就完全蒸发了。在雨滴大小分布中，这些较小雨滴的提前和完全蒸发，丰富了雨滴蒸发产生的水汽。

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来源期刊

Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics

CiteScore

7.30

自引率

11.40%

发文量

684

期刊介绍： JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.