A satellite based study of pre-monsoon thunderstorms (Nor’westers) over eastern India and their organization into mesoscale convective complexes

Tyagi, Ajit; Sikka, D. R.; Goyal, Suman; Bhowmick, Mansi

doi:10.54302/mausam.v63i1.1446

Cited by 26 publications

(10 citation statements)

References 20 publications

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“…During premonsoon, the eastern parts of India (Gangetic West Bengal, Assam, Odisha, Bihar, and Jharkhand) experience severe TS, locally known as Nor'westers or Kal-Baisakhi (Tyagi et al, 2012). This region is also identified as one of the most unstable (Convective Available Potential Energy, CAPE of ∼1500-3500 J⋅kg −1 ) and a suitable region to produce severe TS with intense rainfall (>7 mm⋅h −1 ) activity compared to other parts of India (Sahu et al, 2020;Sasanka et al, 2023;Tyagi et al, 2011Tyagi et al, , 2013Tyagi et al, 2012). The nonlinear nature of TS dynamics, coupled with their smaller spatial and temporal scales, makes predicting TS events a significant challenge (Osuri et al, 2017;Priya et al, 2021Priya et al, , 2022Rajeevan et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…TS are a systematic natural process that transports heat, moisture, and momentum near the earth's surface to the upper level of the atmosphere to maintain the energy and moisture budget. During premonsoon, the eastern parts of India (Gangetic West Bengal, Assam, Odisha, Bihar, and Jharkhand) experience severe TS, locally known as Nor'westers or Kal-Baisakhi (Tyagi et al, 2012). This region is also identified as one of the most unstable (Convective Available Potential Energy, CAPE of ∼1500-3500 J⋅kg −1 ) and a suitable region to produce severe TS with intense rainfall (>7 mm⋅h −1 ) activity compared to other parts of India (Sahu et al, 2020;Sasanka et al, 2023;Tyagi et al, 2011Tyagi et al, , 2013Tyagi et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Enhanced prediction of premonsoon thunderstorms over eastern India through assimilation of INSAT‐3D sounding data

Priya,

Sasanka,

Osuri

2024

Quart J Royal Meteoro Soc

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The present study assesses the impact of Indian National Satellite 3D (INSAT‐3D)‐derived atmospheric (temperature and relative humidity) profiles on the simulation of severe thunderstorms over eastern India during the premonsoon season. Two sets of numerical experiments, without assimilation (CNTL) and with assimilation of INSAT‐3D profiles (INSAT) have been conducted using the three‐dimensional variational data assimilation system of the Weather Research and Forecasting model for 11 thunderstorm events. Analysis increments are positive with INSAT profile assimilation in the lower to middle atmosphere in the thunderstorm region. The errors in the initial fields have been reduced by approx. 50% after the assimilation. After assimilation, the predictions of the surface fields (2‐m temperature, 2‐m relative humidity, and 10‐m wind speed) have been improved at the mature stage (by 37%, 26%, and 15%) compared to the CNTL. Similar improvements are noticed in the vertical profiles of relative humidity and wind speed in the INSAT experiment. The time and magnitude of updrafts and downdrafts improved in INSAT. After assimilation, rainfall intensity improved in nine cases, and time improved in four cases out of 11. The Critical Success Index (False Alarm Rate) of the INSAT ranges from approx. 0.6–0.15 (∼0.37–0.48) for all thresholds, and are higher (lower) than the CNTL. The rainfall area is improved by 25% for light rainfall, 11% for moderate rainfall, and 2% for heavy rainfall in the INSAT over the CNTL experiment. Overall thunderstorm prediction has been improved with the assimilation of INSAT‐3D data. Thus, the study highlights the viability of INSAT‐3D profiles in improving thunderstorm predictions over eastern India.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Enhanced prediction of premonsoon thunderstorms over eastern India through assimilation of INSAT‐3D sounding data

Priya,

Sasanka,

Osuri

2024

Quart J Royal Meteoro Soc

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“…(i) the east-west oriented region along the foothills of Himalaya and (ii) the northwest to southeast oriented region from sub-Himalayan West Bengal to Tripura. 5,6 Additionally, the monthly average of thunderstorm events is greater than 20 in Guwahati, Shillong, Imphal and Tezpur stations in April. Roy et al 7 showed that the number of thunderstorm days is highest in April and May throughout a zone spanning from the NE to West Bengal.…”

Section: Introductionmentioning

confidence: 99%

Spatio-temporal changes in the pre-monsoon thunderstorm activities of northeast India over the past four decades

Rastogi,

Kuttippurath,

Patel

2024

Environ. Sci.: Atmos.

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“…As an alternative step, satellite‐derived information can be used to detect thunderstorms. For example, Tyagi et al (2012) used cloud top temperature from very high‐resolution radiometer of Kalpana‐1 satellite at a spatial resolution of 8 km in 1‐h intervals to study the premonsoon thunderstorm occurrences in 2009. Previous studies have also used feature‐tracking algorithms to study mesoscale convective systems across the globe (e.g., Da Silva & Haerter, 2023; Feng et al, 2021; Huang et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Thunderstorm detection from GPM IMERG rainfall: Climatology of dynamical and thermodynamical processes over India

Sasanka,

Priya,

Osuri

et al. 2023

Intl Journal of Climatology

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This study aims to (i) prepare a premonsoon thunderstorms database, (ii) understand the thunderstorm frequency, duration and intensity and (iii) composite analysis of dynamic and thermodynamic processes related to thunderstorms over India. The thunderstorm associated rainfall varies across India. Hence, a percentile‐based approach is implemented with the integrated multi‐satellite retrievals for global precipitation measurement (IMERG) dataset at 0.1° resolution to identify thunderstorms for 2001–2021. The 93rd percentile appears to be better for thunderstorm detection, with a success ratio of 82% (642 events are confirmed out of 786 detected) in eastern India. Further analysis indicated that 84% of the detected thunderstorms in eastern and northeastern India are associated with lightning activity. Based on this long‐term (2001–2021) thunderstorm data, the highest frequency of thunderstorms (40–45 events·year−1) is observed over the western foothills of the Himalayas, the northeast region, and the west coast of Kerala. The thunderstorm duration in the eastern and northeastern regions and the southwest coast of India is mostly 0.5–2.5 h, producing heavy rainfall (>7 mm·h−1) due to more moisture content and stronger updrafts. The composite structure of thermodynamic indices exhibits significant spatial variations over India and can be used to differentiate the regions of high thunderstorm activity. The minimum (maximum) convective available potential energy (convective inhibition) value required for thunderstorm development is not uniform throughout the country. However, the composites of K index and total totals index during thunderstorms are mostly uniform. This study highlights the benefits of IMERG rainfall in thunderstorm detection over India and helps to understand the local forcings and the effect of thunderstorm activity on different sectors like aviation, agriculture and so forth.

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A satellite based study of pre-monsoon thunderstorms (Nor’westers) over eastern India and their organization into mesoscale convective complexes

Cited by 26 publications

References 20 publications

Enhanced prediction of premonsoon thunderstorms over eastern India through assimilation of INSAT‐3D sounding data

Enhanced prediction of premonsoon thunderstorms over eastern India through assimilation of INSAT‐3D sounding data

Spatio-temporal changes in the pre-monsoon thunderstorm activities of northeast India over the past four decades

Thunderstorm detection from GPM IMERG rainfall: Climatology of dynamical and thermodynamical processes over India

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