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Gleick, PH Global Freshwater Resources: Soft Solutions for the 21st Century. Science 302, 1524-1528 (2003).
Tranvik, LJ et al. Lakes and reservoirs as regulators of the carbon cycle and the climate. Limnol. Oceanogr. 54, 2298-2314 (2009).
Alsdorf, D., Rodriguez, E. and Lettenmaier, DP Measuring surface water from space. Rev. Geophys. 45, RG2002 (2007).
Mekonnen, MM & Hoekstra, AY Sustainability: four billion people facing severe water scarcity. Sci. Adv. 2, e1500323 (2016).
Chao, BF, Wu, YH & Li, YS Impact of the water retention of artificial reservoirs on the global sea level. Science 320, 212–215 (2008).
Smith, LC Rivers of Power: How a natural force raised kingdoms, destroyed civilizations, and shaped our world. (Little, Brown, Spark, 2020).
Zhao, G. & Gao, H. Estimation of reservoir evaporative losses in the United States: fusion of remote sensing and modeling approaches. Remote Sens. About. 226, 109-124 (2019).
Deemer, BR et al. Greenhouse gas emissions from reservoir water surfaces: a new global synthesis. BioScience 66, 949–964 (2016).
Cushman, RM Examining the ecological effects of rapidly varying flows downstream of hydroelectric facilities. N. Am. J. Fish. Manage. 5, 330–339 (1985).
Google Scholar
Pelicice, FM, Pompeu, PS & Agostinho, AA Large reservoirs as ecological barriers to downstream movements of migratory neotropical fish. Fish fish. 16, 697–715 (2015).
Google Scholar
Gillespie, BR, Desmet, S., Kay, P., Tillotson, MR & Brown, LE A critical analysis of the responses of regulated river ecosystems to managed environmental flows from reservoirs. Freshw. Biol. 60, 410–425 (2015).
Google Scholar
Wang, J., Sheng, Y., Gleason, CJ & Wada, Y. Levels downstream of the Yangtze River impacted by the Three Gorges Dam. About. Difference. Become. 8, 044012 (2013).
Kondolf, GM, Rubin, ZK & Minear, JT dams on the Mekong: cumulative sediment starvation. Water Resour. Res. 50, 5158–5169 (2014).
Pekel, J.-F., Cottam, A., Gorelick, N. & Belward, AS High-resolution mapping of global surface water and its long-term changes. Nature 540, 418–422 (2016).
Shiklomanov, AI, Lammers, RB & Vorosmarty, CJ Widespread decline in hydrological monitoring threatens panarctic research. Eos 83, 13–17 (2002).
Lawford, R., Strauch, A., Toll, D., Fekete, B. & Cripe, D. Earth observations for global water security. Curr. Opin. About. Support. 5, 633–643 (2013).
Google Scholar
Gao, H., Birkett, C. & Lettenmaier, DP Global storage monitoring of large reservoirs using satellite remote sensing. Water Resour. Res. 48, W09504 (2012).
Gao, H. Satellite remote sensing of large lakes and reservoirs: from altitude and area to storage. Wiley Interdiscip. Rev. Water 2, 147-157 (2015).
Google Scholar
Zhou, T., Nijssen, B., Gao, H. & Lettenmaier, DP The contribution of reservoirs to global variations in land surface water storage. J. Hydrometeorol. 17, 309–325 (2016).
Rodell, M., Famiglietti, JS, Wiese, DN, Reager, JT & Beaudoing, HK Emerging trends in global freshwater availability. Nature 557, 651-659 (2018); correction 565, E7 (2019).
Getirana, A., Kumar, S., Girotto, M. & Rodell, M. Rivers and floodplains as a key component of global variability in terrestrial water storage. Geophys. Res. Lett. 44, 10359-10368 (2017).
Lehner, B. et al. High resolution mapping of reservoirs and dams around the world for sustainable management of river flow. Forehead. School. About. 9, 494–502 (2011).
Google Scholar
Mulligan, M., van Soesbergen, A. & Sáenz, L. GOODD, a global dataset of over 38,000 georeferenced dams. Sci. Data 7, 31 (2020).
Lehner, B. & Döll, P. Development and validation of a global database of lakes, reservoirs and wetlands. J. Hydrol. 296, 1–22 (2004).
Smith, LC, Sheng, Y. & MacDonald, GM A first pan-arctic assessment of the influence of glaciation, permafrost, topography, and peatlands on the distribution of lakes in the Northern Hemisphere. Permafr. Periglac. Treat. 18, 201-208 (2007).
Google Scholar
Ryan, JC, Smith, LC, Cooley, SW, Pitcher, LH & Pavelsky, TM Global characterization of indoor water reservoirs using ICESat-2 altimetry and climate reanalysis. Geophys. Res. Lett. 47, 1–10 (2020).
Google Scholar
Markus, T. et al. Ice, Cloud and Land Elevation Satellite-2 (ICESat-2): Scientific Requirements, Concept and Implementation Remote Sens. About. 190, 260-273 (2017).
Biancamaria, S., Lettenmaier, DP & Pavelsky, TM The SWOT mission and its capabilities in terrestrial hydrology. Surv. Geophys. 37, 307–337 (2016).
Marzeion, B., Cogley, JG, Richter, K. & Parkes, D. Attribution of global glacier mass loss to anthropogenic and natural causes. Science 345, 919–921 (2014).
Zemp, M. et al. Global ice mass changes and their contributions to sea level rise from 1961 to 2016. Nature 568, 382-386 (2019); correction 577, E9 (2020).
Hansen, MC et al. High resolution global maps of the evolution of forest cover in the 21st century. Science 342, 850–853 (2013).
Taubert, F. et al. Global models of tropical forest fragmentation. Nature 554, 519-522 (2018).
Nienhuis, JH et al. The global human impact on the morphology of the delta has resulted in a net gain in land area. Nature 577, 514-518 (2020).
Syvitski, JPM, Vorosmarty, CJ, Kettner, AJ & Green, P. Impact of humans on land-based sediment flow to the global coastal ocean. Science 308, 376–380 (2005).
Rodell, M., Velicogna, I. & Famiglietti, JS Satellite estimates of groundwater depletion in India. Nature 460, 999-1002 (2009).
Famiglietti, JS The global groundwater crisis. Nat. Clim. Exchange 4, 945–948 (2014).
Grill, G. et al. Mapping the world’s free-flowing rivers. Nature 569, 215-221 (2019); correction 572, E9 (2019).
Neumann, TA et al. The Ice, Cloud and Land Elevation Satellite Mission – 2: a global geolocated photonic product derived from the advanced topographic laser altimeter system. Remote Sens. About. 233, 111325 (2019).
Neuenschwander, AL et al. ATLAS / ICESat-2 L3A Height of land and vegetation, version 3 (NASA National Snow and Ice Data Center Distributed Active Archive Center, accessed October 20, 2020); https://nsidc.org/data/ATL08/versions/3
Neuenschwander, A. & Pitts, K. The terrestrial and plant product ATL08 for the ICESat-2 mission. Remote Sens. About. 221, 247–259 (2019).
Neuenschwander, AL and Pitts, K. Theoretical Algorithm Base Document (ATBD) for overland-vegetated products (ATL08) Version 002 https://icesat-2.gsfc.nasa.gov/sites/default/files/page_files/ICESat2_ATL08_ATBD_r002_v2.pdf (2019).
Yamazaki, D. et al. MERIT Hydro: A high resolution global hydrographic map based on the latest topographic data set. Water Resour. Res. 55, 5053–5073 (2019).
Birkett, CM et al. G-REALM: A lake / reservoir monitoring tool for water resources and regional security assessment. In American Geophysical Union Fall Meeting https://agu.confex.com/agu/fm18/meetingapp.cgi/Paper/374138 (2018).
Lehner, B. & Grill, G. Global river hydrography and network routing: baseline data and new approaches to study the world’s major river systems. Hydrol. Process 27, 2171-2186 (2013).
World Flow Data Center. Main river basins of the world (Federal Institute of Hydrology, consulted on May 15, 2020); https://www.bafg.de/GRDC/EN/02_srvcs/22_gslrs/221_MRB/riverbasins_node.html
Parrish, CE et al. Validation of ICESat-2 ATLAS bathymetry and analysis of ATLAS bathymetric mapping performance. Remote Sens. 11, 1634 (2019).
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