A Rating Curve Model Accounting for Cyclic Stage‐Discharge Shifts due to Seasonal Aquatic Vegetation

Perret, Emeline; Renard, Benjamin; Coz, Jérôme Le

doi:10.1029/2020wr027745

Cited by 17 publications

(8 citation statements)

References 54 publications

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“…Missed peak events in modelling the upper catchment could be due to multiple factors including the complex distribution of SWO thresholds that were spatially variable within the catchment or high heterogeneity of urban precipitation inputs (Liu & Niyogi, 2019; Lorenz et al, 2019). Given the limited number of these events, and their occurrence during summer, peak flows also may be uncertain due to limited measurements to characterize peak flow rating curves (Sikorska et al, 2013; Westerberg & McMillan, 2015) and/or the impact of vegetation in the channel overbank increasing rating curve uncertainty during peak flow events when over bank flow occurs (Perret et al, 2020). Furthermore, while heterogeneity in precipitation sources was incorporated within the modelling framework, known uncertainties particularly of convective precipitation heterogeneities within urban landscapes likely affect event‐based discharge simulations during summer (Meierdiercks et al, 2010; Singh et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

Enhancing urban runoff modelling using water stable isotopes and ages in complex catchments

Smith

Tetzlaff

Marx

et al. 2023

Hydrological Processes

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Increased urbanization, coupled with the projected impacts of climatic change, mandates further evaluation of the impact of urban development on water flow paths to guide sustainable land-use planning. Though the general urbanization impacts of increased storm runoff peaks and reduced baseflows are well known; how the complex, non-stationary interaction of the dominant water fluxes within dynamic urban water stores sustain streamflow regimes over longer periods of time is less well quantified. In particular, there is a challenge in how hydrological modelling should integrate the juxtaposition of rapid and slower flow pathways of the urban 'karst' landscape and different approaches need evaluation. In this context, we utilized hydrological and water stable isotope datasets within a modelling framework that combined the commonly used Hydrologic Engineering Center Hydrological Modelling System (HEC-HMS) urban runoff model along with a simple hydrological tracer module and transit time modelling to evaluate the spatial and temporal variation of water flow paths and ages within a heavily urbanized 217 km 2 catchment in Berlin, Germany. Deeper groundwater was the primary flow component in the upper reaches of the catchment within fewer urbanized regions, while the addition of wastewater effluent in the mid-reaches of the catchment was the dominant water supply to sustain baseflow in the lower main stem stream, with additional direct storm runoff and shallow subsurface contributions in the more urbanized lower reaches. Water ages from each modelling approach mirrored flow contributions and water age mixing potential in subsurface storage; with older average water and lower young water contributions in less urbanized sub-catchments and younger average water and higher young water contributions in more urbanized regions. The results from the first step towards more integrated tracer-aided hydrologic modelling tools for similar peri-urban catchments, given the potential limitations of simpler model frameworks. The results have broader implications for assessing the uncertainty in evaluating urban impacts on hydrological function under environmental change.

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Section: Discussionmentioning

confidence: 99%

Enhancing urban runoff modelling using water stable isotopes and ages in complex catchments

Smith

Tetzlaff

Marx

et al. 2023

Hydrological Processes

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“…The potential for temporal variability that results from seasonal changes in roughness due to weed and vegetation growth (Perret et al, 2021) can be assessed from photos, aerial images and site visits. Vegetation such as leaves and debris can often block small v-notch weirs, resulting in artificially raised water levels and temporally varying systematic overestimation.…”

Section: Station Characteristicsmentioning

confidence: 99%

Sharing perceptual models of uncertainty: On the use of soft information about discharge data

Westerberg,

Karlsen

2024

Hydrological Processes

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Many hydrologists face the situation of having little or no information about the uncertainty in the hydrometeorological data they are using (e.g., Addor et al., 2020). Data uncertainty is rarely communicated by monitoring agencies and data providers-and is often not available on request. This means that data users typically treat data as if they are error-free, whereas in reality there can be large uncertainties and errors (McMillan et al., 2012). A striking example is that 50% of 1523 site-months of discharge data were found to be unreliable in a recent evaluation of the National Ecological Observatory Network streamflow estimates

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“…Reitan and Petersen-Øverleir (2011) developed a dynamic model based on time-varying RC parameters within a hierarchical Bayesian framework. Finally, in the specific context of sites affected by aquatic vegetation, Puechberty et al (2017) proposed time-varying stage corrections and Perret et al (2021) introduced the Bayesian estimation of a time-dependent rating curve model accounting for vegetation growth and decay, with year-specific parameters.…”

Section: Detecting and Modeling Transient Changesmentioning

confidence: 99%

“…(2017) proposed time‐varying stage corrections and Perret et al. (2021) introduced the Bayesian estimation of a time‐dependent rating curve model accounting for vegetation growth and decay, with year‐specific parameters.…”

Section: Introductionmentioning

confidence: 99%

Detection of Stage‐Discharge Rating Shifts Using Gaugings: A Recursive Segmentation Procedure Accounting for Observational and Model Uncertainties

Darienzo

Renard

Coz

et al. 2021

Water Resources Research

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Introduction Rating CurvesRiver discharge, or streamflow, is one of the most important variables in hydrology and hydraulics. Hydrometric data are essential for the calibration of hydrological models, flood forecasting and warning, engineering design (of dam and bridges for example), and policy decisions related to water resources and environmental management. However, streamflow time series are not direct observations as streamflow cannot generally be continuously measured in natural rivers. Instead, the water level (also called "stage") is continuously monitored. Streamflow time series is hence derived from rating curves (Rantz, 1982; WMO, 2010), hereafter called "RCs", which are models transforming an input stage into an output discharge. These models are estimated using occasional stage-discharge measurements (also known as gaugings) and hydraulic constraints. The physical relation between discharge and stage is determined by hydraulic controls, that is, physical characteristics of the river section or channel influencing the flow: geometry, friction, longitudinal slope, head losses, etc. A hydraulic analysis of the site, through field expertize or modeling, allows identifying the succession or addition of hydraulic controls as flow increases (Le Coz et al., 2014).RCs are affected by many sources of uncertainty, including structural uncertainty (imperfection of the RC model), gaugings measurement uncertainty, and parametric uncertainty (estimation of RC parameters).

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A Rating Curve Model Accounting for Cyclic Stage‐Discharge Shifts due to Seasonal Aquatic Vegetation

Cited by 17 publications

References 54 publications

Enhancing urban runoff modelling using water stable isotopes and ages in complex catchments

Enhancing urban runoff modelling using water stable isotopes and ages in complex catchments

Sharing perceptual models of uncertainty: On the use of soft information about discharge data

Detection of Stage‐Discharge Rating Shifts Using Gaugings: A Recursive Segmentation Procedure Accounting for Observational and Model Uncertainties

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