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1. Substantial root-zone water storage capacity observed by GRACE and GRACE/FO

   https://doi.org/10.5194/hess-29-2293-2025  

   Zhao, Meng; McCormick, Erica L; A, Geruo; Konings, Alexandra G; Li, Bailing (May 2025, Hydrology and Earth System Sciences)

   Abstract. Root-zone water storage capacity (Sr) – the maximum water volume available for vegetation uptake – bolsters ecosystem resilience to droughts and heatwaves, influences land–atmosphere exchange, and controls runoff and groundwater recharge. In land models, Sr serves as a critical parameter to simulate water availability for vegetation and its impact on processes like transpiration and soil moisture dynamics. However, Sr is difficult to measure, especially at large spatial scales, hindering an accurate understanding of many biophysical processes, such as photosynthesis, evapotranspiration, tree mortality, and wildfire risk. Here, we present a global estimate of Sr using measurements of total water storage (TWS) anomalies from the Gravity Recovery and Climate Experiment (GRACE) and GRACE Follow-On satellite missions. We find that the median Sr value for global vegetated regions is at least 220±40 mm, which is over 50 % larger than the latest estimate derived from tracking storage change via water fluxes and 380 % larger than that calculated using a typical soil and rooting-depth parameterization. These findings reveal that plant-available water stores exceed the storage capacity of 2 m deep soil in nearly half of Earth's vegetated surface, representing a notably larger extent than previous estimates. Applying our Sr estimates in a global hydrological model improves evapotranspiration simulations compared to other Sr estimates across much of the globe, particularly during droughts, highlighting the robustness of our approach. Our study highlights the importance of continued refinement and validation of Sr estimates and provides a new observational approach for further exploring the impacts of Sr on water resource management and ecosystem sustainability. 

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2. Leading Satellite‐Based Evapotranspiration Products Insufficiently Capture Interannual Variability: Evidence From GRACE/FO and In Situ Observations

   https://doi.org/10.1029/2025GL116784  

   Zhao, Yanni; Hoeltgebaum, Lucas_Emilio B; Kukal, Meetpal S; Zhao, Meng (October 2025, Geophysical Research Letters)

   Abstract Satellite‐based evapotranspiration (ET) products such as OpenET and GLEAM are widely used for drought monitoring and ecosystem‐climate studies. However, their ability to accurately capture interannual variability (IAV), a key requirement for such applications, remains under‐evaluated. Here, we assessed IAV in OpenET and GLEAM using an independent water balance approach that combined precipitation, discharge, and GRACE/FO total water storage anomalies across nine river basins in the western United States. Even after accounting for observational uncertainty through a Monte Carlo approach, both products systematically underestimate IAV relative to water balance‐based ET, by more than 60% on average. This result is further supported by long‐term tower measurements from AmeriFlux. We also demonstrated that ET sensitivity to climate and vegetation drivers in OpenET and GLEAM differ substantially from water balance‐based estimates. These findings reveal important limitations in satellite‐based ET products and highlight the need for improved IAV representation to support ecosystem and climate applications. 

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3. Joint Inversion of GNSS and GRACE for Terrestrial Water Storage Change in California

   https://doi.org/10.1029/2021JB023135  

   Carlson, G.; Werth, S.; Shirzaei, M. (March 2022, Journal of Geophysical Research: Solid Earth)

   Abstract Global Navigation Satellite System (GNSS) vertical displacements measuring the elastic response of Earth's crust to changes in hydrologic mass have been used to produce terrestrial water storage change (∆TWS) estimates for studying both annual ∆TWS as well as multi‐year trends. However, these estimates require a high observation station density and minimal contamination by nonhydrologic deformation sources. The Gravity Recovery and Climate Experiment (GRACE) is another satellite‐based measurement system that can be used to measure regional TWS fluctuations. The satellites provide highly accurate ∆TWS estimates with global coverage but have a low spatial resolution of ∼400 km. Here, we put forward the mathematical framework for a joint inversion of GNSS vertical displacement time series with GRACE ∆TWS to produce more accurate spatiotemporal maps of ∆TWS, accounting for the observation errors, data gaps, and nonhydrologic signals. We aim to utilize the regional sensitivity to ∆TWS provided by GRACE mascon solutions with higher spatial resolution provided by GNSS observations. Our approach utilizes a continuous wavelet transform to decompose signals into their building blocks and separately invert for long‐term and short‐term mass variations. This allows us to preserve trends, annual, interannual, and multi‐year changes in TWS that were previously challenging to capture by satellite‐based measurement systems or hydrological models, alone. We focus our study in California, USA, which has a dense GNSS network and where recurrent, intense droughts put pressure on freshwater supplies. We highlight the advantages of our joint inversion results for a tectonically active study region by comparing them against inversion results that use only GNSS vertical deformation as well as with maps of ∆TWS from hydrological models and other GRACE solutions. We find that our joint inversion framework results in a solution that is regionally consistent with the GRACE ∆TWS solutions at different temporal scales but has an increased spatial resolution that allows us to differentiate between regions of high and low mass change better than using GRACE alone. 

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4. Monitoring Terrestrial Water Storage, Drought and Seasonal Changes in Central Oklahoma With Ambient Seismic Noise

   https://doi.org/10.1029/2023GL103419  

   Zhang, Shuo; Luo, Bingxu; Ben‐Zion, Yehuda; Lumley, David_E; Zhu, Hejun (September 2023, Geophysical Research Letters)

   Abstract Significant imbalances in terrestrial water storage (TWS) and severe drought have been observed around the world as a consequence of climate changes. Improving our ability to monitor TWS and drought is critical for water‐resource management and water‐deficit estimation. We use continuous seismic ambient noise to monitor temporal evolution of near‐surface seismic velocity,dv/v, in central Oklahoma from 2013 to 2022. The deriveddv/vis found to be negatively correlated with gravitational measurements and groundwater depths, showing the impact of groundwater storage on seismic velocities. The hydrological effects involving droughts and recharge of groundwater occur on a multi‐year time scale and dominate the overall derived velocity changes. The thermoelastic response to atmospheric temperature variations occurs primarily on a yearly timescale and dominates the superposed seasonal velocity changes in this study. The occurrences of droughts appear simultaneously with local peaks ofdv/v, demonstrating the sensitivity of near‐surface seismic velocities to droughts. 

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5. Multi-decadal hydrologic change and variability in the Amazon River basin: understanding terrestrial water storage variations and drought characteristics

   https://doi.org/10.5194/hess-23-2841-2019  

   Chaudhari, Suyog; Pokhrel, Yadu; Moran, Emilio; Miguez-Macho, Gonzalo (January 2019, Hydrology and Earth System Sciences)

   Abstract. We investigate the interannual and interdecadalhydrological changes in the Amazon River basin and its sub-basins duringthe 1980–2015 period using GRACE satellite data and a physically based, 2 kmgrid continental-scale hydrological model (LEAF-Hydro-Flood) that includes aprognostic groundwater scheme and accounts for the effects of land use–landcover (LULC) change. The analyses focus on the dominant mechanisms thatmodulate terrestrial water storage (TWS) variations and droughts. We findthat (1) the model simulates the basin-averaged TWS variations remarkablywell; however, disagreements are observed in spatial patterns of temporaltrends, especially for the post-2008 period. (2) The 2010s is the driestperiod since 1980, characterized by a major shift in the decadal mean comparedto the 2000s caused by increased drought frequency. (3) Long-term trends in TWSsuggest that the Amazon overall is getting wetter (1.13 mm yr−1), but itssouthern and southeastern sub-basins are undergoing significant negative TWSchanges, caused primarily by intensified LULC changes. (4) Increasingdivergence between dry-season total water deficit and TWS release suggests astrengthening dry season, especially in the southern and southeasternsub-basins. (5) The sub-surface storage regulates the propagation ofmeteorological droughts into hydrological droughts by strongly modulatingTWS release with respect to its storage preceding the drought condition. Oursimulations provide crucial insight into the importance of sub-surface storagein alleviating surface water deficit across Amazon and open pathways forimproving prediction and mitigation of extreme droughts under changingclimate and increasing hydrologic alterations due to human activities (e.g.,LULC change). 

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