Terrestrial ecosystem response to flash droughts over India

Terrestrial ecosystem response to flash droughts over India

•The RI approach was used to understand the characteristics of flash droughts.•The study was carried out over 25 major river basins of India.•Investigates how the regional terrestrial carbon dynamics respond to flash droughts.•Additionally, the response of WUE to flash droughts was also investigated...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) Vol. 605; p. 127402
Main Authors: Poonia, Vikas, Kumar Goyal, Manish, Jha, Srinidhi, Dubey, Saket
Format: Journal Article
Language:English
Published: Elsevier B.V 01-02-2022
Subjects:
Ecosystem
Flash drought
GPP
Soil moisture
Triple collocation
WUE
uWUE
NASA
Soil moisture
GPP
WUE
Ecosystem
Flash drought
Triple collocation
CCI
VPD
MODIS
ET
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Summary:•The RI approach was used to understand the characteristics of flash droughts.•The study was carried out over 25 major river basins of India.•Investigates how the regional terrestrial carbon dynamics respond to flash droughts.•Additionally, the response of WUE to flash droughts was also investigated. Rapid onset droughts, termed as “flash droughts”, cause short-term but serious threats to terrestrial ecosystems and influence carbon dynamics due to insufficient warning. To date, how the regional terrestrial carbon dynamics respond to flash droughts in India remains unknown. Since, India is highly dependent on its cropland and vegetation, identifying the influence of flash droughts on terrestrial ecosystem is important. Here we use MODIS remote sensing satellite sensor based gross primary productivity (GPP) and remote sensing-based soil moisture data to compute the response of ecosystems to flash droughts in India. From the investigation, it was observed that GPP responds to more than 95% of the flash droughts across India, with the highest response frequency occurring over Ganga basin and southern India while the lowest response across northeastern India. The discrepancies in the response frequencies are mainly attributed to different vegetation resilience conditions across different parts of the country. Moreover, the mean response time is about 10 to 19 days averaged over India, with the lowest and highest response time over Indus-Ganga basins and northeastern Indian river basins (including the Brahmaputra, Minor rivers draining into Myanmar basin (MRMB), and Barak basins), respectively. Severe reduction in water use efficiency (WUE) was observed for the Ganga river basin and some parts of southern India, which highlighted the non-resilient nature of ecosystem towards rapid soil moisture variations. The study facilitates the identification of flash drought hotspots in the country including the Indus basin, Southern river basins (Cauveri, EFRPCP, and EFRSCB basins), some parts of the Ganga basin, and the ability of an ecosystem to withstand such drastic conditions. These findings highlight the need to adopt essential drought mitigation measures to safeguard the sustainability of ecosystems.
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2021.127402