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1. GRACE Detected Rise of Groundwater in the Sahelian Niger River Basin: Niger River Basin Water Storage Rise

   https://doi.org/10.1002/2017JB014845  

   Werth, S. ; White, D. ; Bliss, D. W. ( December 2017 , Journal of Geophysical Research: Solid Earth)
2. Spatial and temporal patterns of dissolved organic matter quantity and quality in the Mississippi River Basin, 1997-2013: Mississippi River Basin DOC quantity and quality trends

   https://doi.org/10.1002/hyp.11072  

   Stackpoole, Sarah M. ; Stets, Edward G. ; Clow, David W. ; Burns, Douglas A. ; Aiken, George R. ; Aulenbach, Brent T. ; Creed, Irena F. ; Hirsch, Robert M. ; Laudon, Hjalmar ; Pellerin, Brian A. ; et al ( February 2017 , Hydrological Processes)
3. Species of Garra (Cyprinidae: Labeoninae) in the Salween River basin with description of an enigmatic new species from the Ataran River drainage of Thailand and Myanmar

   https://doi.org/10.11646/zootaxa.5311.3.3  

   TANGJITJAROEN, WEERAPONGSE ; RANDALL, ZACHARY S. ; TONGNUNUI, SAMPAN ; BOYD, DAVID A. ; PAGE, LAWRENCE M. ( June 2023 , Zootaxa)

   Garra panitvongi, new species, is described from the Ataran River drainage, Salween River basin, of southeastern Myanmar and western Thailand. It is the sixth species of Garra known from the Salween River basin and is readily distinguished from all congeners by the red-orange color of the body and caudal fin, and a pointed proboscis with a blue stripe on each side from the anterior margin of the orbit to the tip of the proboscis and with the stripes forming a V-shape. Garra panitvongi is known in the aquarium trade as the Redtail Garra. Descriptive information is provided on poorly known species of Garra in the Salween River basin, and Garra nujiangensis is transferred to Ageneiogarra. 

    

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4. River flow decline across the entire Arkansas River Basin in the 21st century

   https://doi.org/10.1016/j.jhydrol.2023.129253  

   Yang, Jia ; Zou, Chris ; Will, Rodney ; Wagner, Kevin ; Ouyang, Ying ; King, Chad ; Winrich, Abigail ; Tian, Hanqin ( March 2023 , Journal of Hydrology)

   The Arkansas River and its tributaries provide critical water resources for agricultural irrigation, hydropower generation, and public water supply in the Arkansas River Basin (ARB). However, climate change and other environmental factors have imposed significant impacts on regional hydrological processes, resulting in widespread ecological and economic consequences. In this study, we projected future river flow patterns in the 21st century across the entire ARB under two climate and socio-economic change scenarios (i.e., SSP2-RCP45 and SSP5-RCP85) using the process-based Dynamic Land Ecosystem Model (DLEM). We designed “baseline simulations” (all driving factors were kept constant at the level circa 2000) and “environmental change simulations” (at least one driving factor changed over time during 2001–2099) to simulate the inter-annual variations of river flow and quantify the contributions of four driving factors (i.e., climate change, CO2 concentration, atmospheric nitrogen deposition, and land use change). Results showed that the Arkansas River flow in 2080–2099 would decrease by 12.1% in the SSP2-RCP45 and 27.9% in the SSP5-RCP85 compared to that during 2000–2019. River flow decline would occur from the beginning to the middle of this century in the SSP2-RCP45 and happen throughout the entire century in the SSP5-RCP85. All major rivers in the ARB would experience river flow decline with the largest percentage reduction in the western and southwestern ARB. Warming and drying climates would account for 77%–95% of the reduction. The rising CO2 concentration would exacerbate the decline through increasing foliage area and ecosystem evapotranspiration. This study provides insight into the spatial patterns of future changes in water availability in the ARB and the underlying mechanisms controlling these changes. This information is critical for designing watershed-specific management strategies to maintain regional water resource sustainability and mitigate the adverse impacts of climate changes on water availability. 

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5. Examining the Food-Energy-Water-Environment Nexus in Transboundary River Basins through a Human Dimension Lens: Columbia River Basin

   https://doi.org/10.1061/(ASCE)WR.1943-5452.0001461  

   Zhang, Jiaorui ; Yang, Yi-Chen Ethan ; Li, Hongyi ; Shittu, Ekundayo ( October 2021 , Journal of Water Resources Planning and Management)