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Observational Constraints on Warm Cloud Microphysical Processes Using Machine Learning and Optimization Techniques

J. Christine Chiu, C. Kevin Yang, Peter Jan van Leeuwen, Graham Feingold, Robert Wood, Yann Blanchard, Fan Mei, Jian Wang

2020Geophysical Research Letters37 citationsDOIOpen Access PDF

Abstract

We introduce new parameterizations for autoconversion and accretion rates that greatly improve representation of the growth processes of warm rain. The new parameterizations capitalize on machine-learning and optimization techniques and are constrained by in situ cloud probe measurements from the recent Atmospheric Radiation Measurement Program field campaign at Azores. The uncertainty in the new estimates of autoconversion and accretion rates is about 15% and 5%, respectively, outperforming existing parameterizations. Our results confirm that cloud and drizzle water content are the most important factors for determining accretion rates. However, for autoconversion, in addition to cloud water content and droplet number concentration, we discovered a key role of drizzle number concentration that is missing in current parameterizations. The robust relation between autoconversion rate and drizzle number concentration is surprising but real, and furthermore supported by theory. Thus, drizzle number concentration should be considered in parameterizations for improved representation of the autoconversion process.

Topics & Concepts

DrizzleAccretion (finance)Environmental scienceCloud computingLiquid water contentMeteorologyCloud physicsRepresentation (politics)Atmospheric sciencesComputer scienceAstrophysicsPhysicsPoliticsPolitical scienceOperating systemLawAtmospheric aerosols and cloudsMeteorological Phenomena and SimulationsAtmospheric chemistry and aerosols