Abstract
Global warming-induced melting and thawing of the cryosphere are severely altering the volume and timing of water supplied from High Mountain Asia, adversely affecting downstream food and energy systems that are relied on by billions of people. The construction of more reservoirs designed to regulate streamflow and produce hydropower is a critical part of strategies for adapting to these changes. However, these projects are vulnerable to a complex set of interacting processes that are destabilizing landscapes throughout the region. Ranging in severity and the pace of change, these processes include glacial retreat and detachments, permafrost thaw and associated landslides, rock–ice avalanches, debris flows and outburst floods from glacial lakes and landslide-dammed lakes. The result is large amounts of sediment being mobilized that can fill up reservoirs, cause dam failure and degrade power turbines. Here we recommend forward-looking design and maintenance measures and sustainable sediment management solutions that can help transition towards climate change-resilient dams and reservoirs in High Mountain Asia, in large part based on improved monitoring and prediction of compound and cascading hazards.
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Data availability
The data shown in the figures are available in the publications cited and at https://github.com/geolidf/HMA-hydropower. Air-temperature data are sourced from the China Meteorological Administration. Satellite images are available from the ESA/EC Copernicus Sentinels Scientific Data Hub (Sentinel-2 data) and the United States Geological Survey (Landsat data). Glacier boundary is available at the Randolph Glacier Inventory (RGI 6.0; https://www.glims.org/RGI/rgi60_dl.html). Data on existing and planned HPPs are available at the Global Dam Watch (http://globaldamwatch.org/fhred/; http://globaldamwatch.org/grand/). Data on hydropower potential and developed hydropower are available from the International Hydropower Association (IHA; https://www.hydropower.org/status-report).
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Acknowledgements
This work was supported by Singapore MOE (R-109-000-273-112 and R-109-000-227-115; X.L., D.L.), Cuomo Foundation and IPCC Scholarship Award (D.L.), Swiss National Science Foundation (IZLCZ2_169979/1; T.B.), European Research Council under the European Union’s Horizon 2020 programme (676819; W.W.I., J.F.S.), Netherlands Organisation for Scientific Research (NWO) under the research programme VIDI (016.161.308; W.W.I., J.F.S.), NSFC (42171086; Y.N.), Natural Sciences and Engineering Research Council (NSERC) of Canada (04207-2020; D.H.S.) and Water and Air theme of ICIMOD (S.N., J.F.S.). We thank I. Overeem, A. Kettner, J. Syvitski and IAG DENUCHANGE working group for discussions on erosion and sediment fluxes. The views and interpretations in this publication are those of the authors and are not necessarily attributable to their organizations.
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D.L. and X.L. conceived the study. D.L. wrote the original draft. X.L., D.E.W., T.B., T.Z., R.J.W. and S.H. edited the initial version and contributed ideas. D.L. and T.Z. designed the figures and the Box. J.F.S. contributed to Fig. 4a,b. S.N. contributed to the Box. Y.N. and A.Y. contributed data on GLOFs. X.S. contributed to Supplementary Figs. 1–3. All authors contributed to ideas and edits of subsequent revisions.
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Li, D., Lu, X., Walling, D.E. et al. High Mountain Asia hydropower systems threatened by climate-driven landscape instability. Nat. Geosci. 15, 520–530 (2022). https://doi.org/10.1038/s41561-022-00953-y
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DOI: https://doi.org/10.1038/s41561-022-00953-y
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