Dynamical and thermodynamical interactions in daily precipitation regimes in the Western Himalayas

Battula, Suma Bhanu; Siems, Steven T.; Mondal, Arpita

doi:10.1002/joc.7511

Cited by 3 publications

(2 citation statements)

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“…They argued that the vertical structure of the moisture flux was important in such cases: moisture transport at 700 hPa had the strongest control on variability, and transport at altitudes greater than 500 hPa typically passed over the orography unimpeded. Battula et al (2022) corroborated this transport argument in their climatological study, further arguing that strong WDs are the only weather system capable of pushing moisture to high altitudes in the Western Himalaya. This transport can result in substantial diabatic heating and subsequent intensification of the WD (Hasan and Pattnaik, 2024).…”

Section: °Nmentioning

confidence: 52%

Western disturbances and climate variability: a review of recent developments

Hunt,

Baudouin,

Turner

et al. 2024

Preprint

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Abstract. Western disturbances (WDs) are synoptic-scale weather systems embedded within the subtropical westerly jet. Manifesting as upper-level troughs often associated with a lower-tropospheric low over Western India, they share some dynamical features with extratropical cyclones. WDs are most common during the boreal winter (December to March), during which they bring the majority of precipitation – both rain and snow – to the Western Himalaya, as well as to surrounding areas of north India, Pakistan and the Tibetan Plateau. WDs are also associated with weather hazards such as heavy snowfall, hailstorms, fog, cloudbursts, avalanches, frost, and coldwaves. In this paper, we review the recent understanding and development on WDs. Recent studies have collectively made use of novel data, novel analysis techniques, and the increasing availability of high-resolution weather and climate models. This review is separated into six main sections – structure and thermodynamics, precipitation and impacts, teleconnections, modelling experiments, forecasting at a range of scales, and paleoclimate and climate change – each motivated with a brief discussion of the accomplishments and limitations of previous research. A number of step changes in understanding are synthesised. Use of new modelling frameworks and tracking algorithms has significantly improved knowledge of WD structure and variability, and a more frequentist approach can now be taken. Improved observation systems have helped quantification of water security over the Western Himalaya. Convection-permitting models have improved our understanding of how WDs interact with the Himalayas to trigger natural hazards. Improvements in paleoclimate and future climate modelling experiments have helped to explain how WDs and their impacts over the Himalaya respond to large-scale natural and anthropogenic forcings. We end by summarising unresolved questions and outlining key future WD research topics.

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Section: °Nmentioning

confidence: 52%

Western disturbances and climate variability: a review of recent developments

Hunt,

Baudouin,

Turner

et al. 2024

Preprint

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“…The rainfall in August 2022 exceeded 726% in Sindh and 590% in Balochistan, exceeding the record set in 2010, making it the most intense precipitation event on record (Chughtai 2022, PMD 2022. Previous studies on extreme rainfall in Pakistan have primarily examined the high-frequency time scale and the northern part of the country (Hong et al 2011, Hunt et al 2018, Battula et al 2021. Few studies have investigated the extreme rainfall events in the densely populated southern part of Pakistan.…”

Section: Introductionmentioning

confidence: 99%

The impact of tropical sea surface temperature on extreme precipitation in Pakistan during the summer of 2022

Luo,

Liu,

Zhang

et al. 2024

Environ. Res. Lett.

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In August 2022, Pakistan experienced an unprecedented precipitation event that caused significant damage. Analysis of the observations reveals that this extreme rainfall is primarily driven by anomalous atmospheric zonal advection, resulting in an anomalous water vapor concentration in Pakistan. The climatological meridional advection also contributes to this flooding. Anomalous easterly winds and low-level vertical convection combine to be critical factors contributing to the moisture concentration over the country. Further investigation identifies the air-sea interaction over the tropical Indian Ocean and abnormal warming over the Arabian Sea are crucial factors influencing this extreme flooding event. The concurrent occurrence of a negative Indian Ocean Dipole event and the warming sea surface temperature anomalies (SSTA) in the northern Arabian Sea intensifies the easterly winds over Pakistan, helping to transfer the anomalous water vapor from the remote region into Pakistan, ultimately contributing to the extreme flooding in 2022.

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