Spatiotemporal Variations in the Characteristics of Mesoscale Convective Systems Over Indian Monsoon Zone

IF 3.4 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Geophysical Research: Atmospheres Pub Date : 2025-02-25 DOI:10.1029/2024JD042344

Manisha Tupsoundare, Sachin M. Deshpande, Zhe Feng, Subrata Kumar Das, Medha Deshpande, Harshad Hanmante

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引用次数: 0

Abstract

This study examines cloud and precipitation properties of mesoscale convective systems (MCSs) in the Indian monsoon zone using 6 years of high-resolution satellite-based tracking data. MCSs exhibit strong regional and seasonal variations, peaking during the summer monsoon (June–September). Concentrated along a southeast-northwest band of the monsoon trough, MCS contribute 40%–70% of total precipitation and predominantly move westward at an average speed of 6.3 m s⁻¹. Long-lived MCSs (>40 hr), although 10 times less frequent than short-lived MCSs (5–20 hr), produce 2–3 times more rainfall. Longer MCS lifespans and higher rainfall are associated with stronger deep-layer wind shear and enhanced lower free-tropospheric moisture at initiation. Land and ocean MCSs exhibit distinct diurnal cycles. Most land-based MCSs initiate around 16 LT and mature at 18 LT, whereas Bay of Bengal (BoB) MCSs initiate between 04 and 06 LT and peak by 14 LT. Convective precipitations from MCSs significantly surpasses that from non-MCSs systems, emphasizing their critical role in intense monsoon rainfall. Short- and long-lived MCSs showed distinct lifecycle evolution. Long-lived MCSs over the BoB show 37% larger cold-cloud shields, 44% larger precipitation feature areas, and 33% higher rain rates than their land counterparts, yielding 67% more total rainfall. These BoB MCSs also grow faster and experience more frequent cloud mergers early in their lifecycle. These findings offer critical insights into monsoonal MCSs lifecycle evolution, providing observational constraints for improving model simulations of monsoonal convection.

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印度季风区中尺度对流系统特征的时空变化

本研究利用6年高分辨率卫星跟踪数据，研究了印度季风区中尺度对流系统（mcs）的云和降水特性。mcs表现出强烈的区域和季节变化，在夏季风（6 - 9月）期间达到峰值。MCS集中在季风槽的东南-西北带，贡献了总降水的40%-70%，主要以平均6.3 m s - 1的速度向西移动。长寿命mcs（40小时）虽然比短寿命mcs（5-20小时）少10倍，但产生的降雨量是短寿命mcs（5-20小时）的2-3倍。较长的MCS寿命和较高的降雨量与较强的深层风切变和开始时较低的自由对流层湿度有关。陆地和海洋MCSs表现出明显的日循环。大多数陆基mcs在16lt左右启动，18lt成熟，而孟加拉湾（BoB） mcs在04 - 06 LT启动，14lt达到峰值。来自mcs的对流降水显著超过非mcs系统，强调了它们在强季风降雨中的关键作用。短寿命和长寿命mcs表现出不同的生命周期演化。BoB上的长寿命mcs显示出37%的冷云屏蔽，44%的降水特征面积，33%的降雨率比陆地上的mcs高，总降雨量增加67%。这些BoB mcs的增长速度更快，并且在其生命周期的早期经历了更频繁的云合并。这些发现为季风mcs生命周期演变提供了重要见解，为改进季风对流的模式模拟提供了观测约束。

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来源期刊

Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics

CiteScore

7.30

自引率

11.40%

发文量

684

期刊介绍： JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.