Distinct aerosol effects on cloud-to-ground lightning in the plateau and basin regions of Sichuan, Southwest China
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Published:2020-11-11
Issue:21
Volume:20
Page:13379-13397
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ISSN:1680-7324
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Container-title:Atmospheric Chemistry and Physics
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language:en
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Short-container-title:Atmos. Chem. Phys.
Author:
Zhao Pengguo, Li ZhanqingORCID, Xiao Hui, Wu Fang, Zheng YoutongORCID, Cribb Maureen C., Jin Xiaoai, Zhou Yunjun
Abstract
Abstract. The joint effects of aerosol, thermodynamic, and cloud-related factors on cloud-to-ground
lightning in Sichuan were investigated by a comprehensive analysis of ground-based measurements made
from 2005 to 2017 in combination with reanalysis data. Data include aerosol optical depth,
cloud-to-ground (CG) lightning density, convective available potential energy (CAPE), mid-level
relative humidity, lower- to mid-tropospheric vertical wind shear, cloud-base height, total column
liquid water (TCLW), and total column ice water (TCIW). Results show that CG lightning density and
aerosols are positively correlated in the plateau region and negatively correlated in the basin
region. Sulfate aerosols are found to be more strongly associated with lightning than total
aerosols, so this study focuses on the role of sulfate aerosols in lightning activity. In the
plateau region, the lower aerosol concentration stimulates lightning activity through
microphysical effects. Increasing the aerosol loading decreases the cloud droplet size, reducing the
cloud droplet collision–coalescence efficiency and inhibiting the warm-rain process. More small
cloud droplets are transported above the freezing level to participate in the freezing process,
forming more ice particles and releasing more latent heat during the freezing process. Thus, an
increase in the aerosol loading increases CAPE, TCLW, and TCIW, stimulating CG lightning in the
plateau region. In the basin region, by contrast, the higher concentration of aerosols inhibits
lightning activity through the radiative effect. An increase in the aerosol loading reduces the amount
of solar radiation reaching the ground, thereby lowering the CAPE. The intensity of convection
decreases, resulting in less supercooled water being transported to the freezing level and fewer ice
particles forming, thereby increasing the total liquid water content. Thus, an increase in the
aerosol loading suppresses the intensity of convective activity and CG lightning in the basin
region.
Funder
National Natural Science Foundation of China
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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