Sediment Management for Reservoir Sustainability and Cost Implications Under Land Use/Land Cover Change Uncertainty

Addressing uncertainty in sediment predictions due to land use/land cover (LULC) change could better inform the selection of sediment management options for reservoir sustainability. We used the Nam Kong catchment of the Mekong River Basin in Southern Laos, with two hydropower dams in series, to und...

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Bibliographic Details
Published in:Water resources research 2021-04, Vol.57 (4), p.n/a
Main Authors: Shrestha, Bikesh, Cochrane, Thomas A., Caruso, Brian S., Arias, Mauricio E., Wild, Thomas B.
Format: Article
Language:English
Subjects:
Bottom trawling
Catchment area
Catchments
Costs
Dams
Dredging
Economic models
Economics
Flushing
Flushing (water)
Hydroelectric dams
Hydroelectric power
Hydrologic models
Land cover
Land use
land use/land cover
reservoir
Reservoir capacity
Reservoir storage
Reservoirs
River basins
Sediment
sediment management
Sediments
Soil water
Sustainability
Terracing
Tillage
Uncertainty
Variability
Water purification
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Summary:Addressing uncertainty in sediment predictions due to land use/land cover (LULC) change could better inform the selection of sediment management options for reservoir sustainability. We used the Nam Kong catchment of the Mekong River Basin in Southern Laos, with two hydropower dams in series, to understand the implications of LULC change uncertainty for catchment‐level and reservoir‐level sediment management options. The catchment‐level sediment management options of terracing, vegetative filter strips, and no tillage were evaluated applying the Soil and Water Assessment Tool (SWAT). The reservoir‐level sediment management option of flushing was assessed using the Sediment Simulation Screening Python Model (PySedSim). Costs of sediment management options were assessed via the economic value of the loss in hydropower production and the avoided cost of dredging. Our results suggest that LULC projections resulted in high variability in loss of reservoir capacity and cost of sediment management. Terracing was found to be the best catchment‐level management option at decreasing both the magnitude and variability in loss of reservoir storage for both dams, but it was also the most expensive option. Flushing was also effective in reducing sedimentation, but it was less economically beneficial compared to catchment‐level sediment management options. Combinations of catchment‐level and reservoir‐level management strategies, however, can be effective in reducing the magnitude and variability in loss of reservoir storage and associated costs in response to LULC change uncertainty. Key Points Costs of sediment management options are linked to the economic value of the loss in hydropower production and the avoided cost of dredging The sediment management strategy best at increasing the life span of a reservoir may not be the most cost‐effective option to implement Integration of suitable sediment management options can reduce the amount and variability in reservoir storage loss and associated cost
ISSN:0043-1397
1944-7973
DOI:10.1029/2020WR028351