Mon Oct 13, F. Flechtner
• Sorted by Date • Sorted by Last Name of First Author •
Huang, Haijun, Cai, Xitian, Li, Lu, Wu, Xiaolu, Zhao, Zichun, and Tan, Xuezhi, 2025. Interpreting Global Terrestrial Water Storage Dynamics and Drivers with Explainable Deep Learning. Remote Sensing, 17(13):2118, doi:10.3390/rs17132118.
• from the NASA Astrophysics Data System • by the DOI System •
@ARTICLE{2025RemS...17.2118H,
author = {{Huang}, Haijun and {Cai}, Xitian and {Li}, Lu and {Wu}, Xiaolu and {Zhao}, Zichun and {Tan}, Xuezhi},
title = "{Interpreting Global Terrestrial Water Storage Dynamics and Drivers with Explainable Deep Learning}",
journal = {Remote Sensing},
keywords = {global terrestrial water storage, spatio-temporal pattern analysis, driving factor analysis, explainable deep learning},
year = 2025,
month = jun,
volume = {17},
number = {13},
eid = {2118},
pages = {2118},
abstract = "{Sustained reductions in terrestrial water storage (TWS) have been
observed globally using Gravity Recovery and Climate Experiment
(GRACE) satellite data since 2002. However, the underlying
mechanisms remain incompletely understood due to limited record
lengths and data discontinuity. Recently, explainable artificial
intelligence (XAI) has provided robust tools for unveiling
dynamics in complex Earth systems. In this study, we employed a
deep learning technique (Long Short-Term Memory network, LSTM)
to reconstruct global TWS dynamics, filling gaps in the GRACE
record. We then utilized the Local Interpretable Model-agnostic
Explanations (LIME) method to uncover the underlying mechanisms
driving observed TWS reductions. Our results reveal a consistent
decline in the global mean TWS over the past 22 years
(2002{\textendash}2024), primarily influenced by precipitation
(17.7\%), temperature (16.0\%), and evapotranspiration (10.8\%).
Seasonally, the global average of TWS peaks in April and reaches
a minimum in October, mirroring the pattern of snow water
equivalent with approximately a one-month lag. Furthermore, TWS
variations exhibit significant differences across latitudes and
are driven by distinct factors. The largest declines in TWS
occur predominantly in high latitudes, driven by rising
temperatures and significant snow/ice variability. Mid-latitude
regions have experienced considerable TWS losses, influenced by
a combination of precipitation, temperature, air pressure, and
runoff. In contrast, most low-latitude regions show an increase
in TWS, which the model attributes mainly to increased
precipitation. Notably, TWS losses are concentrated in coastal
areas, snow- and ice-covered regions, and areas experiencing
rapid temperature increases, highlighting climate change
impacts. This study offers a comprehensive framework for
exploring TWS variations using XAI and provides valuable
insights into the mechanisms driving TWS changes on a global
scale.}",
doi = {10.3390/rs17132118},
adsurl = {https://ui.adsabs.harvard.edu/abs/2025RemS...17.2118H},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
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Mon Oct 13, F. Flechtner