Mon Oct 13, F. Flechtner
• Sorted by Date • Sorted by Last Name of First Author •
Li, Xuliang, Xue, Yayong, Wu, Di, Tan, Shaojun, Cao, Xue, and Zhao, Wusheng, 2025. Precipitation Governs Terrestrial Water Storage Anomaly Decline in the Hengduan Mountains Region, China, Amid Climate Change. Remote Sensing, 17(14):2447, doi:10.3390/rs17142447.
• from the NASA Astrophysics Data System • by the DOI System •
@ARTICLE{2025RemS...17.2447L,
author = {{Li}, Xuliang and {Xue}, Yayong and {Wu}, Di and {Tan}, Shaojun and {Cao}, Xue and {Zhao}, Wusheng},
title = "{Precipitation Governs Terrestrial Water Storage Anomaly Decline in the Hengduan Mountains Region, China, Amid Climate Change}",
journal = {Remote Sensing},
keywords = {terrestrial water storage anomaly, climate drivers, Hengduan Mountains region, drought risk, water resources management},
year = 2025,
month = jul,
volume = {17},
number = {14},
eid = {2447},
pages = {2447},
abstract = "{Climate change intensifies hydrological cycles, leading to an increased
variability in terrestrial water storage anomalies (TWSAs) and a
heightened drought risk. Understanding the spatiotemporal
dynamics of TWSAs and their driving factors is crucial for
sustainable water management. While previous studies have
primarily attributed TWSAs to regional factors, this study
employs wavelet coherence, partial correlation analysis, and
multiple linear regression to comprehensively analyze TWSA
dynamics and their drivers in the Hengduan Mountains (HDM)
region from 2003 to 2022, incorporating both regional and global
influences. Additionally, dry{\textendash}wet variations were
quantified using the GRACE-based Drought Severity Index (GRACE-
DSI). Key findings include the following: The annual mean TWSA
showed a non-significant decreasing trend (‑2.83 mm/y, p >
0.05), accompanied by increased interannual variability.
Notably, approximately 36.22\% of the pixels in the western HDM
region exhibited a significantly decreasing trend. The Nujiang
River Basin (NRB) (‑17.17 mm/y, p < 0.01) and the Lancang
(‑17.17 mm/y, p < 0.01) River Basin experienced the most
pronounced declines. Regional factors{\textemdash}particularly
precipitation (PRE){\textemdash}drove TWSA in 59\% of the HDM
region, followed by potential evapotranspiration (PET, 28\%) and
vegetation dynamics (13\%). Among global factors, the North
Atlantic Oscillation showed a weak correlation with TWSAs (r =
‑0.19), indirectly affecting it via winter PET (r = ‑0.56, p <
0.05). The decline in TWSAs corresponds to an elevated drought
risk, notably in the NRB, which recorded the largest GRACE-DSI
decline (slope = ‑0.011, p < 0.05). This study links TWSAs to
climate drivers and drought risk, offering a framework for
improving water resource management and drought preparedness in
climate-sensitive mountain regions.}",
doi = {10.3390/rs17142447},
adsurl = {https://ui.adsabs.harvard.edu/abs/2025RemS...17.2447L},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
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