Relative Importance of Large‐Scale Environmental Variables to the World‐Wide Variability of Thunderstorms

This study uses a 16‐yr Tropical Rainfall Measuring Mission (TRMM) Convective Features (CFs) and ERA‐Interim reanalysis data to investigate the relative importance of four large‐scale environmental variables to thunderstorms with random forest models. These four variables include Convective Availabl...

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Published in:Journal of geophysical research. Atmospheres 2022-09, Vol.127 (17), p.n/a
Main Authors: Liu, Nana, Liu, Chuntao, Tissot, Philippe E.
Format: Article
Language:English
Subjects:
Capes (landforms)
Convective available potential energy
Geographical distribution
Geophysics
Lightning
Lightning flashes
Modelling
Potential energy
Rainfall
Random variables
relative importance
thermodynamic
Thunderstorms
Tropical rainfall
Tropical Rainfall Measuring Mission (TRMM)
Variables
Weather
Wind shear
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container_title Journal of geophysical research. Atmospheres
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creator Liu, Nana
Liu, Chuntao
Tissot, Philippe E.
description This study uses a 16‐yr Tropical Rainfall Measuring Mission (TRMM) Convective Features (CFs) and ERA‐Interim reanalysis data to investigate the relative importance of four large‐scale environmental variables to thunderstorms with random forest models. These four variables include Convective Available Potential Energy (CAPE), Convective Inhibition (CIN), low‐level wind shear, and warm cloud depth (WCD). First, these selected four environmental variables show a distinguished difference between CFs with and without lightning flashes. Specifically, CFs with at least one flash have higher CAPE, CIN, and lower WCD than those without lightning. Then, using these four variables, the geographical distribution of thunderstorms, especially the land‐ocean contrast in the occurrence of thunderstorms, is closely reproduced with a global random forest model. Such results suggest that a random forest model with key large‐scale environmental variables can be a useful tool to estimate the occurrence of global lightning thunderstorms. The study also investigates the relative importance of the selected variables to the occurrence of thunderstorms regionally. Relatively higher skill scores in the regional random forest model than the global one indicate the variation of roles of large scale environment variables over different regions. Though the data‐driven models can be utilized to estimate the occurrence of global thunderstorms, how to link the regional relative importance of these variable to the physical processes of thunderstorms needs further investigation. Key Points The geographical distribution of thunderstorms is closely reproduced by a global random forest model The regional and global random forest models can be used to investigate the relative importance of different large‐scale variables for thunderstorm over different regions Convective available potential energy, convective inhibition, and warm cloud depth are confirmed as important variables to parameterize convective intensity at the sub‐grid scale in climate model
doi_str_mv 10.1029/2021JD036065
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These four variables include Convective Available Potential Energy (CAPE), Convective Inhibition (CIN), low‐level wind shear, and warm cloud depth (WCD). First, these selected four environmental variables show a distinguished difference between CFs with and without lightning flashes. Specifically, CFs with at least one flash have higher CAPE, CIN, and lower WCD than those without lightning. Then, using these four variables, the geographical distribution of thunderstorms, especially the land‐ocean contrast in the occurrence of thunderstorms, is closely reproduced with a global random forest model. Such results suggest that a random forest model with key large‐scale environmental variables can be a useful tool to estimate the occurrence of global lightning thunderstorms. The study also investigates the relative importance of the selected variables to the occurrence of thunderstorms regionally. Relatively higher skill scores in the regional random forest model than the global one indicate the variation of roles of large scale environment variables over different regions. Though the data‐driven models can be utilized to estimate the occurrence of global thunderstorms, how to link the regional relative importance of these variable to the physical processes of thunderstorms needs further investigation. Key Points The geographical distribution of thunderstorms is closely reproduced by a global random forest model The regional and global random forest models can be used to investigate the relative importance of different large‐scale variables for thunderstorm over different regions Convective available potential energy, convective inhibition, and warm cloud depth are confirmed as important variables to parameterize convective intensity at the sub‐grid scale in climate model</description><identifier>ISSN: 2169-897X</identifier><identifier>EISSN: 2169-8996</identifier><identifier>DOI: 10.1029/2021JD036065</identifier><language>eng</language><publisher>Washington: Blackwell Publishing Ltd</publisher><subject>Capes (landforms) ; Convective available potential energy ; Geographical distribution ; Geophysics ; Lightning ; Lightning flashes ; Modelling ; Potential energy ; Rainfall ; Random variables ; relative importance ; thermodynamic ; Thunderstorms ; Tropical rainfall ; Tropical Rainfall Measuring Mission (TRMM) ; Variables ; Weather ; Wind shear</subject><ispartof>Journal of geophysical research. 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Atmospheres</title><description>This study uses a 16‐yr Tropical Rainfall Measuring Mission (TRMM) Convective Features (CFs) and ERA‐Interim reanalysis data to investigate the relative importance of four large‐scale environmental variables to thunderstorms with random forest models. These four variables include Convective Available Potential Energy (CAPE), Convective Inhibition (CIN), low‐level wind shear, and warm cloud depth (WCD). First, these selected four environmental variables show a distinguished difference between CFs with and without lightning flashes. Specifically, CFs with at least one flash have higher CAPE, CIN, and lower WCD than those without lightning. Then, using these four variables, the geographical distribution of thunderstorms, especially the land‐ocean contrast in the occurrence of thunderstorms, is closely reproduced with a global random forest model. Such results suggest that a random forest model with key large‐scale environmental variables can be a useful tool to estimate the occurrence of global lightning thunderstorms. The study also investigates the relative importance of the selected variables to the occurrence of thunderstorms regionally. Relatively higher skill scores in the regional random forest model than the global one indicate the variation of roles of large scale environment variables over different regions. Though the data‐driven models can be utilized to estimate the occurrence of global thunderstorms, how to link the regional relative importance of these variable to the physical processes of thunderstorms needs further investigation. 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2169-8996
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subjects Capes (landforms)
Convective available potential energy
Geographical distribution
Geophysics
Lightning
Lightning flashes
Modelling
Potential energy
Rainfall
Random variables
relative importance
thermodynamic
Thunderstorms
Tropical rainfall
Tropical Rainfall Measuring Mission (TRMM)
Variables
Weather
Wind shear
title Relative Importance of Large‐Scale Environmental Variables to the World‐Wide Variability of Thunderstorms
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