Present and Future Losses of Storage in Large Reservoirs Due to Sedimentation: A Country-Wise Global Assessment

Perera, Duminda; Williams, Spencer; Smakhtin, Vladimir

doi:10.3390/su15010219

Cited by 26 publications

(4 citation statements)

References 30 publications

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“…3 of Federal Law on the Use of Water Power), but this could be questioned. The lifetime of the potential reservoirs is, however, reduced by sedimentation (Perera, Williams, & Smakhtin, 2023), as shown by the example of the existing Gebidem Reservoir, located downstream of the Aletsch Glacier and which could be filled within only 20-30 years . The development of new lakes will also induce risks related to landslides or rock/ice avalanches into the lake, generating lake outburst floods; the risk is exacerbated by the degradation of permafrost on the surrounding slopes and by glacial debuttressing (Cathala, Magnin, Linsbauer, & Haeberli, 2021;Haeberli et al, 2013Haeberli et al, , 2017.…”

Section: Futurementioning

confidence: 99%

Conservation of World Heritage glacial landscapes in a changing climate: The Swiss Alps Jungfrau-Aletsch case

Bussard,

Reynard

2024

Preprint

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Many glacial landscapes on all continents are inscribed on the World Heritage List. Due to climate change, most of the glaciers are retreating rapidly, thus questioning their Outstanding Universal Value (OUV). Ice loss could indeed reduce or modify the heritage values of the UNESCO World Heritage properties where glaciers are the core of the OUV and even question their inscription on the World Heritage List. In a future with fewer or without glaciers, at least two components of the OUV of World Heritage glacial landscapes could be affected: the aesthetic value (criterion vii), which could be reduced if glaciers disappear, and the geoheritage value (criterion viii), which is partly based on current glaciological processes that would no longer exist without ice. This presentation aims to clarify what constitute the heritage values of glacial landscapes and outlines how they could evolve in a future with less (or without) ice. For two sites in the UNESCO Swiss Alps Jungfrau-Aletsch property (the Great Aletsch Glacier and the Upper Lauterbrunnen Valley), we describe the evolution of the glacial landscape using a Past-Present-Future framework. We then evaluate the present and post-glacial heritage values according to criteria used in the literature on geomorphosites. We outline two main issues: 1. The two sites are characterized by a very high palaeogeographical interest: the inherited glacial landforms around the Great Aletsch Glacier and Lake Oberhorn have allowed the reconstruction of Holocene glacial stages. In the future, the inherited landforms of high palaeogeographical interest and the para- and periglacial processes that develop in post-glacier conditions are likely to gain interest, while the dynamics of the glacier itself, which is an important part of the current geoscientific value, will decline and even be lost when the glacier disappears. As glaciers retreat, the geoscientific value will therefore depend more and more on the inherited glacial landforms, which allow the understanding of the Earth and climate history, and less and less on the glacier itself and its dynamics. As the inherited landforms can be fragile, are non-renewable and will become more central to the heritage value, their protection is an issue. 2. The aesthetic value of glacial landscapes could decrease because of the disappearance of the glacier (landscape greying). One possible adaptation could be a shift from glacier tourism, which is mainly oriented towards the contemplation of an aesthetic landscape, to geotourism, where the understanding of landscape evolution is proposed to the public.

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Section: Futurementioning

confidence: 99%

Conservation of World Heritage glacial landscapes in a changing climate: The Swiss Alps Jungfrau-Aletsch case

Bussard,

Reynard

2024

Preprint

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“…For example, storage capacity (reservoirs) should be maintained, i.e., sediment accumulation in reservoirs needs to be evaluated (something that has not been carried out, as previously mentioned) and controlled, if needed. Indeed, sediment accumulation is the biggest problem that reservoirs face around the world, resulting in a worldwide loss of around 20% storage capacity [39], also decreasing the lifespan of the structures. There are ways to prevent this from happening in Arequipa (see [40]).…”

Section: Future Scenarios: Water Usagementioning

confidence: 99%

Water Resources Evaluation and Sustainability Considering Climate Change and Future Anthropic Demands in the Arequipa Region of Southern Peru

Quiroz,

Garcia-Chevesich,

Martínez

et al. 2023

Sustainability

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Climate change and increases in human activities are threatening water availability in the Arequipa Region (southern Peru). However, to date, there has not been a comprehensive inventory of surface water data or an investigation of current surface water conditions or forecasted future conditions resulting from increased anthropic demand or stresses from climate change. This study evaluates surface water resources management including storage, diversions, and conveyance in the Arequipa Region, while creating a tool for the evaluation of future scenarios in the five main watersheds of this arid region of southern Peru. State-of-the art, open-source modeling software was used. Water uses for each watershed were evaluated against predicted reservoir inflows and streamflows for different periods. In addition to the above, 12 climate change models and different shared socioeconomic pathways (SSP) were ensembled for the five watersheds. A semi-distributed approach and an innovative simulation splitting approach was used for each watershed, which allowed for different starting dates for the simulations using all available data obtained from different sources (government and private). Results indicate that the region is expected to have increased flows during the wet season and no significant changes during the dry season. Reservoir inflows are expected to increase up to 42 and 216% for the lowest and highest SSP evaluated, respectively. Similarly, the model projected streamflow increases up to 295 and 704%, respectively. Regarding yearly water availability and considering current and future demands for the watersheds under study, water deficits are not expected in the future if current reservoir storage can be maintained, though it is expected that reservoirs won’t be able to store predicted higher flows, so important volumes of water could be lost during the wet season to the ocean by natural drainage. Given the uncertainty of climate change projections, if future water sustainability is desired, storage and irrigation efficiencies should be improved and reservoir sedimentation should be evaluated.

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“…The trend may be even more concerning elsewhere in the world; in both the United Kingdom and Japan, the average large dam is greater than 100 years old (Perera et al, 2021). Beyond evolving design standards, dams globally have lost significant design capacity as they have gradually infilled with sediment, risking failure and constituting a global water storage infrastructure challenge (Perera et al, 2023). Risks associated with dam failure will persist globally in the future, as population growth, economic development and climate change concerns have led to a global proliferation in dam construction centred in developing countries and emerging economies (Zarfl et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Quantifying landscape change following catastrophic dam failures in Edenville and Sanford, Michigan, USA

Martin,

Edmonds,

Yanites

et al. 2024

Earth Surf Processes Landf

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Dam failures due to changing hydroclimate and ageing infrastructure pose a significant threat to downstream river systems and communities. The detailed geomorphic effects of catastrophic dam failures are not well known because of a lack of high‐resolution topographic data before and after failures. On 19 May 2020, the 17‐m‐tall Edenville and 11‐m‐tall Sanford dams near Midland, Michigan, USA, failed as a result of significant rainfall over the preceding 2 days. We analysed the geomorphic impacts of these failures using a pre‐failure airborne lidar dataset and three uncrewed aerial vehicle (UAV)‐based lidar surveys collected 2 weeks, 3 months and 11 months after failure. Our survey following the dam failure revealed 47 100 ± 11 900 m3 of net floodplain erosion and 17 300 ± 4200 m3 of net deposition downstream of the Edenville and Sanford dam breaches, respectively. Over the year following failure, most geomorphic change was confined to new knickpoints migrating slowly through underlying glacial till substrate, with little change to riverbanks or surrounding floodplains. A lack of impounded reservoir sediment and antecedent downstream topography, including valley width and the location of the breaches relative to the river below the dams, contributed to relatively modest geomorphic changes despite the magnitude of water released. We provide insight into how landscapes are shaped by catastrophic floods, which are likely to become more common with ageing dams and a changing hydroclimate.

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Present and Future Losses of Storage in Large Reservoirs Due to Sedimentation: A Country-Wise Global Assessment

Cited by 26 publications

References 30 publications

Conservation of World Heritage glacial landscapes in a changing climate: The Swiss Alps Jungfrau-Aletsch case

Conservation of World Heritage glacial landscapes in a changing climate: The Swiss Alps Jungfrau-Aletsch case

Water Resources Evaluation and Sustainability Considering Climate Change and Future Anthropic Demands in the Arequipa Region of Southern Peru

Quantifying landscape change following catastrophic dam failures in Edenville and Sanford, Michigan, USA

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