Lightning occurrences and intensity over the Indian region: long-term trends and future projections
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Published:2021-07-23
Issue:14
Volume:21
Page:11161-11177
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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:
Chakraborty Rohit, Chakraborty Arindam, Basha GhouseORCID, Ratnam Madineni Venkat
Abstract
Abstract. Lightning activity constitute the major destructive component of
thunderstorms over India. Hence, an understanding of the long-term variability
in lightning occurrence and intensity and their interrelation with various
causative factors is required. Long-term (1998–2014) Tropical Rainfall
Measuring Mission (TRMM) satellite-based lightning observations depict the
most frequent lightning occurrences along the Himalayan foothills, the
Indo-Gangetic plains and coastal regions, while the intensity of these
lightning strikes is found to be strongest along the coastal regions and in the
Bay of Bengal. In addition, both of the abovementioned lightning properties show a very strong
intensification (∼ 1 %–2.5 % annually) across all Indian
regions during the 1998–2014 period with the maximum trends along the coasts.
Accordingly, a detailed statistical dominance analysis is performed which
reveals total column water vapor (TCWV) to be the dominant factor behind the
intensification in lightning events, while instability, measured by the
convective available potential energy (CAPE), and aerosol optical depth
(AOD) jointly control the lightning frequency trends. An increase in surface
temperatures has led to enhanced instability and, hence, stronger moisture
transport to the upper-troposphere and lower-stratosphere regions, especially along the coasts. This transported moisture helps deplete the ozone
concentration, leading to reduced temperatures and elevated equilibrium
levels, which finally results in stronger and more frequent lightning events,
as also evidenced by the trend analysis. Consequently, the relationships
between lightning and its causative factors have been expressed in the form of
multilinear regression equations, which are then employed in multiple global
circulation models (GCMs) to understand the long-term impact of urbanization
on lightning over the period from 1950 to 2100. The analysis reveals a uniform
increase in lightning occurrence and intensity using both urbanization
scenarios; however, accelerated growth is observed in the RCP8.5
projections after the year 2050, as also observed from the surface warming
trends. As a result, lightning frequency and intensity values across the
Indian region are expected to increase ∼ 10 %–25 % and 15 %–50 %, respectively, by the end of the century with the
highest risk along the coasts; hence, this requires immediate attention
from policymakers.
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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