Your search found 2 records
1 Rasanen, T. A.; Someth, P.; Lauri, H.; Koponen, J.; Sarkkula, J.; Kummu, M. 2017. Observed river discharge changes due to hydropower operations in the Upper Mekong Basin. Journal of Hydrology, 545:28-41. [doi: https://doi.org/10.1016/j.jhydrol.2016.12.023]
Water power ; International waters ; Rivers ; Downstream ; Flow discharge ; Development projects ; Hydrological factors ; Models ; Water levels ; Dams ; Reservoirs ; Dry season ; Wet season / Thailand / Cambodia / Upper Mekong Basin / Chiang Saen / Nakhon Phanom / Kratie
(Location: IWMI HQ Call no: e-copy only Record No: H048004)
(1.55 MB)
The Upper Mekong Basin is undergoing extensive hydropower development and its largest dams have recently become operational. Hydropower is built to improve the regional energy supply, but at the same time, it has considerable transboundary impacts on downstream discharge regime and further on aquatic ecosystems, riparian livelihoods and food security. Despite the transboundary significance of the impacts, there is no public information on the hydropower operations or on the already observed downstream discharge impacts since the completion of the largest dams. Therefore, in this study we assess the discharge changes using observed river discharge data and a distributed hydrological model over the period of 1960–2014. Our findings indicate that the hydropower operations have considerably modified the river discharges since 2011 and the largest changes were observed in 2014. According to observed and simulated discharges, the most notable changes occurred in northern Thailand (Chiang Saen) in March-May 2014 when the discharge increased by 121–187% and in July-August 2014 when the discharge decreased by 32–46% compared to average discharges. The respective changes in Cambodia (Kratie) were 41–74% increase in March-May 2014 and 0–6% decrease in July-August 2014 discharges. The earlier model-based predictions of the discharge changes are well in line with the observed changes, although observed changes are partly larger. The discharge impacts are expected to vary from year to year depending on hydropower operations. Altogether, the results highlight the need for strong transboundary cooperation for managing the downstream impacts.
2 Sabo, J. L.; Ruhi, A.; Holtgrieve, G. W.; Elliott, V.; Arias, M. E.; Ngor, P. B.; Rasanen, T. A.; Nam, S. 2017. Designing river flows to improve food security futures in the Lower Mekong Basin. Science, 358(6368):1-11. [doi: https://doi.org/10.1126/science.aao1053]
River basins ; Stream flow ; Discharges ; Food security ; Inland fisheries ; Forecasting ; Dams ; Water power ; Hydrological factors ; Models ; Ecological factors ; Floodplains ; Hydrography / Cambodia / Lower Mekong Basin / Tonle Sap Lake
(Location: IWMI HQ Call no: e-copy only Record No: H048520)
(1.57 MB)
Rivers provide unrivaled opportunity for clean energy via hydropower, but little is known about the potential impact of dam-building on the food security these rivers provide. In tropical rivers, rainfall drives a periodic flood pulse fueling fish production and delivering nutrition to more than 150 million people worldwide. Hydropower will modulate this flood pulse, thereby threatening food security. We identified variance components of the Mekong River flood pulse that predict yield in one of the largest freshwater fisheries in the world. We used these variance components to design an algorithm for a managed hydrograph to explore future yields. This algorithm mimics attributes of discharge variance that drive fishery yield: prolonged low flows followed by a short flood pulse. Designed flows increased yield by a factor of 3.7 relative to historical hydrology. Managing desired components of discharge variance will lead to greater efficiency in the Lower Mekong Basin food system.
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