Return Period of Characteristic Discharges from the Comparison between Partial Duration and Annual Series, Application to the Walloon Rivers (Belgium)

Campenhout, Jean Van; Houbrechts, Geoffrey; Peeters, Alexandre; Petit, François

doi:10.3390/w12030792

Cited by 13 publications

(12 citation statements)

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“…Due to the difficulty of defining the bankfull discharge in the two braided/wandering study cases (Drac and Vénéon rivers), we took the ~1‐year return‐period flood as reference discharge in these two cases. There are three advantages of using the dimensionless flow intensity as flow parameter: (i) Q is the flow descriptor most widely reported in the compiled papers, so this ratio is easy to compute; (ii) the bankfull Q is commonly considered as the dominant channel‐forming discharge and it has been traditionally associated with a 1.5 to 2‐year return period flood (Leopold et al ., 1964), although the exact recurrence of the bankfull flow differs with the hydroclimatic setting and the use of partial vs full duration series (Van Campenhout et al ., 2020); and (iii) the bankfull Q has been consistently related to a near‐threshold discharge for bed sediment movement in gravel‐bed rivers (e.g. Phillips and Jerolmack, 2019).…”

Section: Methodsmentioning

confidence: 99%

The active layer in gravel‐bed rivers: An empirical appraisal

Vázquez‐Tarrío

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et al. 2020

Earth Surf Processes Landf

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The vertical position of the streambed–water boundary fluctuates during the course of sediment transport episodes, due to particle entrainment/deposition and bedform migration, amongst other hydraulic and bedload mechanisms. These vertical oscillations define a topmost stratum of the streambed (i.e. the ‘active layer or active depth’), which usually represents the main source of particles entrained during long and high‐magnitude bedload transport episodes. The vertical extent of this layer is hence a capital parameter for the quantification of bedload volumes and a major driver of stream ecology in gravel‐bed rivers. However, knowledge on how the active depth scales to flow strength and the nature of the different controls on the relation between the flow strength and the active depth is still scarce. In this paper we present a meta‐analysis over active depth data coming from ~130 transport episodes extracted from a series of published field studies. We also incorporate our own field data for the rivers Ebro and Muga (unpublished), both in the Iberian Peninsula. We explore the database searching for the influence of flow strength, grain size, streambed mobility and channel morphology on the vertical extent of the active layer. A multivariate statistical analysis (stepwise multiple regression) confirms that the set of selected variables explains a significant amount of variance in the compiled variables. The analysis shows a positive scaling between active depth and flow strength. We have also identified some links between the active depth and particle travel distances. However, these relations are also largely modulated by other fluvial drivers, such as the grain size of the bed surface and the dominant channel macro‐bedforms, with remarkable differences between plane‐bed, step‐pool and riffle‐pool channels. © 2020 John Wiley & Sons, Ltd.

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Section: Methodsmentioning

confidence: 99%

The active layer in gravel‐bed rivers: An empirical appraisal

Vázquez‐Tarrío

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Vericat

et al. 2020

Earth Surf Processes Landf

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“…The regional classification of stations depends on their location and on the sedimentary setting and the hydrological dynamics of the upstream area. The regional affiliation of each station (Van Campenhout et al 2020) is shown in Table 2 as well as their geological substratum and loess availability. The land cover proportion in each watershed is derived from Copernicus Land Service and the Corine Land Cover maps (Panagos et al 2015;CORINE Land Cover 2018).…”

Section: Study Location: Geographical and Geological Featuresmentioning

confidence: 99%

“…Discharge data from the dataset do not cover the same period at each location because their installation date varies. Figure 2 gives information about the mean number of days per year where discharge is above bankfull discharge (Q b ), which has been observed in the field or computed from partial series with the methodology of Van Campenhout et al (2020). Figure 2 also shows the number of stations with at least 90% of hourly discharge data available for a given year.…”

Section: Hydrologic Series Availabilitymentioning

confidence: 99%

Estimation of the area-specific suspended sediment yield from discrete samples in different regions of Belgium

et al. 2021

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PurposeSuspended sediment transport, which represents the majority of the sediment load, has been studied across very different scales and in a wide variety of regions and climates. Despite numerous studies, data for European watersheds are generally limited and correspond to large rivers systems. Especially, in Belgium, little data is available outside the Belgian loess belt. Moreover, the high heterogeneity of soil erosion and sediment transport makes it difficult to measure or model at watershed scale. The purpose of this research is to estimate the median sediment yields in different geographical regions and to detect their explanatory variables.Materials and methodsGathering data from 1994 to 2016, more than 2000 measurements of suspended sediment concentration at 72 river stations mainly located in South-Belgium were sampled according to a flood-event-based manual methodology. This allowed fast acquisition of data in watersheds ranging from 7 to 3600 km 2 in different geographical regions. Median area-specific sediment yields (SSY) were calculated at watershed scale while looking for regional differences.Results and discussionMedian area-specific sediment yields computed for the period 1996-2018 show regional differences: 19.2 t km −2 year −1 on sandy substrate (Lorraine), 24.9 t km −2 year −1 on schisto-sandstone substratum (Ardenne), and up to 119 t km −2 year −1 in the loamy Brabant plateau, with a link to the agricultural land cover and, to a lesser extent, to the watershed slope. The high temporal and spatial variability of rainfall has great effects on the SSY, necessitating the gathering of more than 20 years of data to smooth the high variability of SSY. A multiple correlation of land cover variables and the average slope of the watershed with SSY managed to explain 48% of the variance within the SSY observations.ConclusionsThe agricultural land cover has an important effect on median SSY values. While the regionalization of Belgium is largely based on lithology, soils, and altitude, the land use resulting from these physical and climatic characteristics explains the differences in SSY. Field values of clogged dams and waterways confirm the matching of the SSY computation from discrete samples, despite the high temporal variability of sediment transport. KeywordsSediment yield • Suspended sediment concentration • Soil erosion rate • Meuse basin • Scheldt basin

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“…Les données hydrologiques utilisées dans cette étude proviennent de la station limnigraphique de Martelange (L5610, SPW-DGO3). Le débit à pleins bords (Q b ) de la Sûre au niveau de cette station est de 32 m³/s et sa période de retour, calculée sur base des séries partielles, est de 0,8 an (Van Campenhout et al, 2020). Le module est de 3,8 m³/s.…”

Section: Zone D'étudeunclassified