Estimating the sediment trap efficiency of intermittently dry reservoirs: lessons from the Kruger National Park, South Africa

Reinwarth, Bastian; Riddell, Edward S.; Glotzbach, Christoph; Baade, Jussi

doi:10.1002/esp.4263

Cited by 9 publications

(5 citation statements)

References 52 publications

(148 reference statements)

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“…One reservoir core was taken at a point of assumed deepest sediment using an Eijkelkamp percussion corer. Reservoir depth information was received on‐site from another research team, data published in Reinwarth et al (2018). The boundary between deposit and reservoir bottom was determined by colour and particle size changes (Baade et al, 2012; Reinwarth et al, 2017; Reinwarth et al, 2018).…”

Section: Methodsmentioning

confidence: 99%

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Application of environmental magnetism to estimate source contribution by lithology to Kruger National Park reservoirs

Miller

Rowntree

Foster

et al. 2022

Hydrological Processes

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Sediment source fingerprinting using environmental magnetism has successfully differentiated between sediment sources in several studies in the Eastern Cape Province of South Africa. The method was applied in this study to the near-natural landscape of southern Kruger National Park (Mpumalanga Province) to trace sediment and determine sediment yields by lithology in four reservoir catchments that were underlain by igneous, metamorphic, and sedimentary rocks. The Park area has no history of cultivation and is a conservation area, so catchment sources were dominated by underlying lithologies. One sediment core was collected in the assumed deepest area of the reservoir. Source discrimination and apportionment were estimated using a common statistical protocol that includes a Mann-Whitney U or Kruskal-Wallis H test, mass conservation test, discriminant function analysis, and an (un)mixing model. A contribution from each lithology-defined source was estimated.Sediment yield by lithology was estimated by using published catchment areaspecific sediment yields in combination with the (un)mixing model. Underlying lithology determined vegetation type and density, and vegetation appeared to play a crucial role in protecting soils and reducing erosion. Proximity to reservoir, that is, travel distance for eroded sediment, and connectivity were also important factors controlling the relative contribution from each potential source. The contributing area for sediment was found to be dynamic through time and was probably dependent on runoff and temporal variations in vegetation cover.

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Section: Methodsmentioning

confidence: 99%

“…This section describes the field sampling, laboratory, and statistical methods used to determine sediment yields. Catchment area (Baade & Schmullius, 2015) and lithology area percentages (Reinwarth et al, 2018) were established from published literature. Catchment lithologies were the sources identified for the fingerprinting method.…”

Section: Methodsmentioning

confidence: 99%

Application of environmental magnetism to estimate source contribution by lithology to Kruger National Park reservoirs

Miller

Rowntree

Foster

et al. 2022

Hydrological Processes

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“…Brune (1953) prepared a standard curve by plotting capacity-inflow (C/I) ratio against sediment trapping efficiency for sites in the USA, and successfully applied it to estimate the percentage of sediment yield based on the sediment trapped. Therefore, the C/I ratio was later selected as the main constituent of the TE index (Romero-Díaz et al, 2012;Parsaie et al, 2018;Reinwarth et al, 2018). In fact, this concept refers to the generalizability of the percentage of inflowing sediment mass that remains permanently in the reservoir.…”

Section: Methodology: the Trap Efficiency Concept And Tool Developmentmentioning

confidence: 99%

“…The sediment trapping efficiency (TE) index has been widely used to assess reservoir sedimentation efficiency Poesen, 2000, 2001;Eizel-Din et al, 2010;Romero-Díaz et al, 2012;Reinwarth et al, 2018;Parsaie et al, 2018). This index estimates the efficiency of check dams based on upstream watershed area and reservoir capacity (Hadley and Walling, 1984;Siyam, 2000).…”

Section: Introductionmentioning

confidence: 99%

TET: An automated tool for evaluating suitable check-dam sites based on sediment trapping efficiency

Rahmati

Ghasemieh

Samadi

et al. 2020

Journal of Cleaner Production

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“…Errors associated with determination of historic sediment yields require attention, but they are small when considering the spatial distribution of event layers [39,40]. Event sediment layers detected in reservoirs, and their derived specific event sediment yields, are very accurate for long-term assessments [41,42], as long as the trap efficiency is known [43,44].…”

Section: Introductionmentioning

confidence: 99%

Fluvial Sediment Yields in Hyper-Arid Areas, Exemplified by Nahal Nehushtan, Israel

Armoza-Zvuloni

Shlomi

Abadi

et al. 2022

Land

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Floods rarely occur in hyper-arid deserts and little is known about the magnitude and frequency of sediment delivery from their basins, despite their importance to changes to the landscape, infrastructures and engineering activities. Sediment yield from the Nahal Nehushtan watershed (11.9 km2) located in the Timna Valley in southern Israel was determined by assessing stratigraphic sections in its 60-year reservoir deposits. Stratigraphic correlation between event couplets allowed for quantification of sediment yields representing 13 former flow and flood events. Based on the sediment volume in the reservoir, the 29.8 t km−2 year−1 average specific sediment yield is one of the lowest among other studied warm deserts. Among the event layers, the thickest layer, deposited by a flash flood caused by a single short rain event, contributed 31% of the total sediment yield. Based on event reservoir sedimentation from watersheds located in several hyper-arid areas in the Middle East and North America, we demonstrate that sediment yield increases with drainage area as expected and mean annual sediment yield increases in hyper-arid areas with flood frequency. Our quantitative results, together with previous studies of hyper-arid areas, provide complementary evidence of fluvial sediment transport—the main landscape designer in hyper-arid fluvial landscapes.

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Estimating the sediment trap efficiency of intermittently dry reservoirs: lessons from the Kruger National Park, South Africa

Cited by 9 publications

References 52 publications

Application of environmental magnetism to estimate source contribution by lithology to Kruger National Park reservoirs

Application of environmental magnetism to estimate source contribution by lithology to Kruger National Park reservoirs

TET: An automated tool for evaluating suitable check-dam sites based on sediment trapping efficiency

Fluvial Sediment Yields in Hyper-Arid Areas, Exemplified by Nahal Nehushtan, Israel

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