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

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 re...

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Published in:Geophysical research letters 2021-01, Vol.48 (2), p.e2020GL091236-n/a
Main Authors: Chiu, J. Christine, Yang, C. Kevin, van Leeuwen, Peter Jan, Feingold, Graham, Wood, Robert, Blanchard, Yann, Mei, Fan, Wang, Jian
Format: Article
Language:English
Subjects:
accretion
Atmospheric Processes
autoconversion
boundary layer cloud
cloud parameterization
Clouds and Aerosols
Clouds and Cloud Feedbacks
ENVIRONMENTAL SCIENCES
Geodesy and Gravity
Global Change
Hydrology
machine learning
Natural Hazards
Precipitation
Remote Sensing
Remote Sensing and Disasters
Remote Sensing of Volcanoes
Research Letter
Space Geodetic Surveys
Volcanology
warm rain
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cited_by cdi_FETCH-LOGICAL-c5200-77952019c8d840ac2ee1396234ac716ea3c79fb8a19f1ecd302cc22fa27d54313
cites cdi_FETCH-LOGICAL-c5200-77952019c8d840ac2ee1396234ac716ea3c79fb8a19f1ecd302cc22fa27d54313
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container_start_page e2020GL091236
container_title Geophysical research letters
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creator Chiu, J. Christine
Yang, C. Kevin
van Leeuwen, Peter Jan
Feingold, Graham
Wood, Robert
Blanchard, Yann
Mei, Fan
Wang, Jian
description 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. Plain Language Summary Drizzle has been a key element of research, because its formation modulates cloud properties and evolution, and affects the water cycle of the Earth. Since drizzle formation involves cloud droplets of all sizes, it requires extensive computational time. Hence, we often use simplified methods in weather and climate prediction models to obtain a bulk estimate of how fast and how many cloud droplets collide with each other or collide with bigger drops to form drizzle. However, many models continue to have inadequate representation of drizzle formation, calling for the need to improve these simplified methods. We introduce new methods to estimate the rate of those microphysical processes, capitalizing on aircraft measurements and recent advances in machine‐learning techniques. Our techniques outperform the current methods significantly. Importantly, our analyses reveal that the rate of drizzle formation via collisions between cloud drops is related to drizzle drop number concentration itself, which is missing in the existing methods. This relation occurs because drizzle drop number concentration provides information on the stage of evolution of cloud size distribution during drizzle formation. Although this is not a causal relationship, it is important to incorporate this relation into models for better prediction of drizzle formation
doi_str_mv 10.1029/2020GL091236
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Christine ; Yang, C. Kevin ; van Leeuwen, Peter Jan ; Feingold, Graham ; Wood, Robert ; Blanchard, Yann ; Mei, Fan ; Wang, Jian</creator><creatorcontrib>Chiu, J. Christine ; Yang, C. Kevin ; van Leeuwen, Peter Jan ; Feingold, Graham ; Wood, Robert ; Blanchard, Yann ; Mei, Fan ; Wang, Jian ; Pacific Northwest National Laboratory (PNNL), Richland, WA (United States) ; National Oceanic and Atmospheric Administration (NOAA), Boulder, CO (United States). NOAA Chemical Sciences Laboratory (CSL) ; Washington Univ., St. Louis, MO (United States)</creatorcontrib><description>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. Plain Language Summary Drizzle has been a key element of research, because its formation modulates cloud properties and evolution, and affects the water cycle of the Earth. Since drizzle formation involves cloud droplets of all sizes, it requires extensive computational time. Hence, we often use simplified methods in weather and climate prediction models to obtain a bulk estimate of how fast and how many cloud droplets collide with each other or collide with bigger drops to form drizzle. However, many models continue to have inadequate representation of drizzle formation, calling for the need to improve these simplified methods. We introduce new methods to estimate the rate of those microphysical processes, capitalizing on aircraft measurements and recent advances in machine‐learning techniques. Our techniques outperform the current methods significantly. Importantly, our analyses reveal that the rate of drizzle formation via collisions between cloud drops is related to drizzle drop number concentration itself, which is missing in the existing methods. This relation occurs because drizzle drop number concentration provides information on the stage of evolution of cloud size distribution during drizzle formation. Although this is not a causal relationship, it is important to incorporate this relation into models for better prediction of drizzle formation. Key Points Machine‐learning trained by in situ data constrains autoconversion and accretion rates with uncertainty of 15% and 5%, respectively There is a surprising relation between autoconversion rate and drizzle number concentration that significantly improves parameterizations The exponent of autoconversion rate dependence on cloud number concentration is 0.75, lower than that in existing parameterizations</description><identifier>ISSN: 0094-8276</identifier><identifier>EISSN: 1944-8007</identifier><identifier>DOI: 10.1029/2020GL091236</identifier><identifier>PMID: 33678926</identifier><language>eng</language><publisher>United States: American Geophysical Union (AGU)</publisher><subject>accretion ; Atmospheric Processes ; autoconversion ; boundary layer cloud ; cloud parameterization ; Clouds and Aerosols ; Clouds and Cloud Feedbacks ; ENVIRONMENTAL SCIENCES ; Geodesy and Gravity ; Global Change ; Hydrology ; machine learning ; Natural Hazards ; Precipitation ; Remote Sensing ; Remote Sensing and Disasters ; Remote Sensing of Volcanoes ; Research Letter ; Space Geodetic Surveys ; Volcanology ; warm rain</subject><ispartof>Geophysical research letters, 2021-01, Vol.48 (2), p.e2020GL091236-n/a</ispartof><rights>2020. 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Christine</creatorcontrib><creatorcontrib>Yang, C. Kevin</creatorcontrib><creatorcontrib>van Leeuwen, Peter Jan</creatorcontrib><creatorcontrib>Feingold, Graham</creatorcontrib><creatorcontrib>Wood, Robert</creatorcontrib><creatorcontrib>Blanchard, Yann</creatorcontrib><creatorcontrib>Mei, Fan</creatorcontrib><creatorcontrib>Wang, Jian</creatorcontrib><creatorcontrib>Pacific Northwest National Laboratory (PNNL), Richland, WA (United States)</creatorcontrib><creatorcontrib>National Oceanic and Atmospheric Administration (NOAA), Boulder, CO (United States). NOAA Chemical Sciences Laboratory (CSL)</creatorcontrib><creatorcontrib>Washington Univ., St. Louis, MO (United States)</creatorcontrib><title>Observational Constraints on Warm Cloud Microphysical Processes Using Machine Learning and Optimization Techniques</title><title>Geophysical research letters</title><addtitle>Geophys Res Lett</addtitle><description>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. 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Hence, we often use simplified methods in weather and climate prediction models to obtain a bulk estimate of how fast and how many cloud droplets collide with each other or collide with bigger drops to form drizzle. However, many models continue to have inadequate representation of drizzle formation, calling for the need to improve these simplified methods. We introduce new methods to estimate the rate of those microphysical processes, capitalizing on aircraft measurements and recent advances in machine‐learning techniques. Our techniques outperform the current methods significantly. Importantly, our analyses reveal that the rate of drizzle formation via collisions between cloud drops is related to drizzle drop number concentration itself, which is missing in the existing methods. This relation occurs because drizzle drop number concentration provides information on the stage of evolution of cloud size distribution during drizzle formation. 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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. Plain Language Summary Drizzle has been a key element of research, because its formation modulates cloud properties and evolution, and affects the water cycle of the Earth. Since drizzle formation involves cloud droplets of all sizes, it requires extensive computational time. Hence, we often use simplified methods in weather and climate prediction models to obtain a bulk estimate of how fast and how many cloud droplets collide with each other or collide with bigger drops to form drizzle. However, many models continue to have inadequate representation of drizzle formation, calling for the need to improve these simplified methods. We introduce new methods to estimate the rate of those microphysical processes, capitalizing on aircraft measurements and recent advances in machine‐learning techniques. Our techniques outperform the current methods significantly. Importantly, our analyses reveal that the rate of drizzle formation via collisions between cloud drops is related to drizzle drop number concentration itself, which is missing in the existing methods. This relation occurs because drizzle drop number concentration provides information on the stage of evolution of cloud size distribution during drizzle formation. Although this is not a causal relationship, it is important to incorporate this relation into models for better prediction of drizzle formation. 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subjects accretion
Atmospheric Processes
autoconversion
boundary layer cloud
cloud parameterization
Clouds and Aerosols
Clouds and Cloud Feedbacks
ENVIRONMENTAL SCIENCES
Geodesy and Gravity
Global Change
Hydrology
machine learning
Natural Hazards
Precipitation
Remote Sensing
Remote Sensing and Disasters
Remote Sensing of Volcanoes
Research Letter
Space Geodetic Surveys
Volcanology
warm rain
title Observational Constraints on Warm Cloud Microphysical Processes Using Machine Learning and Optimization Techniques
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