The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Interactions between subpolar and subtropical jet streams lead to extreme rainfall events over the North Indian Subcontinent in June 2013 and July 2023

Interactions between subpolar and subtropical jet streams lead to extreme rainfall events over the North Indian Subcontinent in June 2013 and July 2023
Interactions between subpolar and subtropical jet streams lead to extreme rainfall events over the North Indian Subcontinent in June 2013 and July 2023
North Indian Subcontinent (NIS) is prone to disastrous and life-threatening floods during the summer monsoon period primarily due to its close proximity with the Himalayan foothills. Indian Meteorological Department (IMD) reported that during June 13-19, 2013, the Uttarakhand state in North India experienced a cumulative total of 322 mm rainfall, a 847% weekly departure against the long-term average rainfall (1971-2020) of 34 mm. After a decade, another state in the same region, Himachal Pradesh, received an unprecedented 223 mm of rainfall in just 4 days, viz 7-11 July 2023, a 436% deviation from the cumulative climatological rainfall of 41.6 mm for 4 days (July 7-11). It is shown that the atmospheric water vapor is transported towards NIS by two monsoon low pressure systems during the June 2013 event. In contrast, during the July 2023 flood, the monsoon trough shifted southward, resulting in the moisture transport pathway predominantly over the northern Indian Ocean. In conjunction, it was shown through upper-level air tracing that southward movement of the subpolar jet stream creates a trough in the subtropical jet stream, which intrudes along the western boundary of NIS, leading to upper-level divergence. This pattern was observed in both flood events. By leveraging the mass-conserving nature and unique capability of a Lagrangian tracing model to track atmospheric water backward in time, our novel analysis of the 2023 flood reveals that two evaporative sources near Madagascar and the western Indian Ocean were key contributors, and inland evaporation played a comparatively lesser role as compared to the 2013 case. The Bay of Bengal served primarily as a vapor transport pathway rather than a direct moisture source for both events. This novel Lagrangian approach, which exposes separate drivers of extreme monsoon rainfall, upstream and at lead times of days-weeks, has the potential to be used more extensively and operationally.
Indian monsoon; Extreme rainfall; Subpolar jet stream; Lagrangian tracing, Subpolar jet stream, Indian monsoon, Extreme rainfall, Lagrangian tracing
0930-7575
Dey, Dipanjan
6abca563-f99d-4554-a0b8-945d5621b16b
Joseph, Ligin
dba8b26c-88ab-4b6b-9b73-e1c890f1593f
Skliris, Nikolaos
07af7484-2e14-49aa-9cd3-1979ea9b064e
Ray, Arkaprava
7b7ca471-4ff3-4b65-8ba1-fff7eb037934
Marsh, Robert
702c2e7e-ac19-4019-abd9-a8614ab27717
Skliris, Nikolaos
07af7484-2e14-49aa-9cd3-1979ea9b064e
Turner, Andrew G.
5e10519a-8dc6-4e01-9430-368b9406c990
Ayantika, D.C.
a4c5ea21-2a23-46e7-ac7c-f0ea54681014
Mukhopadhyay, Parthasarathi
f1564758-80fa-4a4a-805b-37cf82c2ff03
Chakraborty, Arun
dc605d14-e143-42a5-9ee8-62fdff3cc587
Sil, Sourav
20f3caff-f8ef-42cd-99b3-6f96b50f6d34
Dey, Dipanjan
6abca563-f99d-4554-a0b8-945d5621b16b
Joseph, Ligin
dba8b26c-88ab-4b6b-9b73-e1c890f1593f
Skliris, Nikolaos
07af7484-2e14-49aa-9cd3-1979ea9b064e
Ray, Arkaprava
7b7ca471-4ff3-4b65-8ba1-fff7eb037934
Marsh, Robert
702c2e7e-ac19-4019-abd9-a8614ab27717
Skliris, Nikolaos
07af7484-2e14-49aa-9cd3-1979ea9b064e
Turner, Andrew G.
5e10519a-8dc6-4e01-9430-368b9406c990
Ayantika, D.C.
a4c5ea21-2a23-46e7-ac7c-f0ea54681014
Mukhopadhyay, Parthasarathi
f1564758-80fa-4a4a-805b-37cf82c2ff03
Chakraborty, Arun
dc605d14-e143-42a5-9ee8-62fdff3cc587
Sil, Sourav
20f3caff-f8ef-42cd-99b3-6f96b50f6d34

Dey, Dipanjan, Joseph, Ligin, Skliris, Nikolaos, Ray, Arkaprava, Marsh, Robert, Skliris, Nikolaos, Turner, Andrew G., Ayantika, D.C., Mukhopadhyay, Parthasarathi, Chakraborty, Arun and Sil, Sourav (2025) Interactions between subpolar and subtropical jet streams lead to extreme rainfall events over the North Indian Subcontinent in June 2013 and July 2023. Climate Dynamics, 63 (5), [230]. (doi:10.1007/s00382-025-07712-w).

Record type: Article

Abstract

North Indian Subcontinent (NIS) is prone to disastrous and life-threatening floods during the summer monsoon period primarily due to its close proximity with the Himalayan foothills. Indian Meteorological Department (IMD) reported that during June 13-19, 2013, the Uttarakhand state in North India experienced a cumulative total of 322 mm rainfall, a 847% weekly departure against the long-term average rainfall (1971-2020) of 34 mm. After a decade, another state in the same region, Himachal Pradesh, received an unprecedented 223 mm of rainfall in just 4 days, viz 7-11 July 2023, a 436% deviation from the cumulative climatological rainfall of 41.6 mm for 4 days (July 7-11). It is shown that the atmospheric water vapor is transported towards NIS by two monsoon low pressure systems during the June 2013 event. In contrast, during the July 2023 flood, the monsoon trough shifted southward, resulting in the moisture transport pathway predominantly over the northern Indian Ocean. In conjunction, it was shown through upper-level air tracing that southward movement of the subpolar jet stream creates a trough in the subtropical jet stream, which intrudes along the western boundary of NIS, leading to upper-level divergence. This pattern was observed in both flood events. By leveraging the mass-conserving nature and unique capability of a Lagrangian tracing model to track atmospheric water backward in time, our novel analysis of the 2023 flood reveals that two evaporative sources near Madagascar and the western Indian Ocean were key contributors, and inland evaporation played a comparatively lesser role as compared to the 2013 case. The Bay of Bengal served primarily as a vapor transport pathway rather than a direct moisture source for both events. This novel Lagrangian approach, which exposes separate drivers of extreme monsoon rainfall, upstream and at lead times of days-weeks, has the potential to be used more extensively and operationally.

Text
s00382-025-07712-w - Version of Record
Available under License Creative Commons Attribution.
Download (13MB)

More information

Accepted/In Press date: 24 April 2025
Published date: 13 May 2025
Keywords: Indian monsoon; Extreme rainfall; Subpolar jet stream; Lagrangian tracing, Subpolar jet stream, Indian monsoon, Extreme rainfall, Lagrangian tracing
Learn more about School of Ocean and Earth Science research

Identifiers

Local EPrints ID: 503188
URI: http://eprints.soton.ac.uk/id/eprint/503188
DOI: doi:10.1007/s00382-025-07712-w
ISSN: 0930-7575
PURE UUID: a253ac87-57f7-46f0-a8e5-b77293919838
ORCID for Dipanjan Dey: ORCID iD orcid.org/0000-0002-9588-4042
ORCID for Ligin Joseph: ORCID iD orcid.org/0000-0001-6637-0475
ORCID for Nikolaos Skliris: ORCID iD orcid.org/0000-0002-2473-2586
ORCID for Nikolaos Skliris: ORCID iD orcid.org/0000-0002-2473-2586

Catalogue record

Date deposited: 23 Jul 2025 16:40
Last modified: 22 Aug 2025 02:40

Export record

Altmetrics

Contributors

Author: Dipanjan Dey ORCID iD
Author: Ligin Joseph ORCID iD
Author: Nikolaos Skliris ORCID iD
Author: Arkaprava Ray
Author: Robert Marsh
Author: Nikolaos Skliris ORCID iD
Author: Andrew G. Turner
Author: D.C. Ayantika
Author: Parthasarathi Mukhopadhyay
Author: Arun Chakraborty
Author: Sourav Sil

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×