Particle-resolved simulation of antidunes in free-surface flows

Schwarzmeier, Christoph; Rettinger, Christoph; Kemmler, Samuel; Plewinski, Jonas; Núñez‐González, Francisco; Köstler, Harald; Ruede, Ulrich; Vowinckel, Bernhard

doi:10.1017/jfm.2023.262

Cited by 3 publications

(1 citation statement)

References 22 publications

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“…The effect of water flow on the riverbed determines the morphodynamics and hydromorphology of riverbeds [6][7][8]. Mathematical modeling of riverbed processes based on self-consistent accounting of water dynamics [1,9] and sediment transport is an effective tool both for the analysis of channel deformations [10][11][12][13][14], and to provide environmental expertise in the design of hydraulic structures, sand extraction and other anthropogenic impacts. The dynamics of suspended sediments is described by the transport equation [10]:…”

Section: Suspended Sediments Mathematical Modelingmentioning

confidence: 99%

EcoGIS-Simulation Software for riverbed sediments modeling

Khrapov,

Agafonnikova,

Potaptseva

et al. 2023

E3S Web Conf.

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The paper describes the EcoGIS-Simulation software and hardware complex for numerical hydrological modeling of river systems. The computing core makes it possible to carry out a non-stationary self-consistent calculation of the dynamics of surface and groundwater, as well as the transfer of entrained and suspended sediments. The main attention is paid to the organization of geoinformation support for such calculations at the stages of preparation of initial data, processing of results and their visualization. EcoGIS-Simulation software is designed to simulate non-stationary self-consistent dynamics of surface and groundwater together with the transport of entrained and suspended sediments. The strong dependence of the nature of sediment transport on the particle size in the conditions of the Medveditsa River in the vicinity of the city of Mikhailovka (Volgograd Region, Russia) is shown.

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Section: Suspended Sediments Mathematical Modelingmentioning

confidence: 99%

EcoGIS-Simulation Software for riverbed sediments modeling

Khrapov,

Agafonnikova,

Potaptseva

et al. 2023

E3S Web Conf.

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Antidune simulations using continuum‐based models

Escauriaza,

Williams

2024

Earth Surf Processes Landf

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The interactions of supercritical flows with sand or gravel beds in river channels or tidal inlets lead to the formation of antidunes. These bedforms are generally identified as nearly periodic sedimentary patterns of symmetrical shape that are in phase with the surface waves in the flow and have important effects on flow resistance and bedload transport. In addition, they play a fundamental role on morphodynamical processes in estuarine systems, on the scour around hydraulic infrastructure, and their bed signature can help to interpret paleofloods from sedimentary records. Despite the importance and ubiquity of antidunes in environmental flows, very few numerical simulations have captured their dynamics. In this work, we develop a model that couples the shallow‐water and Exner equations in two‐dimensions (2D) and demonstrate that a higher‐level theory can reproduce the experimental antidune results of Pascal et al. (2021), independent of interactions at the particle scale. The flows are characterised by Froude numbers between 1.31 and 1.45, sediment diameters of mm and with 3° mean bed slopes. Using this information, we aim to identify the minimum requirements for a numerical model to capture in detail the migration of these bedforms. We use spectral analysis and compute statistics of bed elevation to determine the relevant temporal and spatial scales associated to the antidune propagation. The results of the model yield new insights on the mechanisms of bedform migration, providing tools to improve their description and assess the morphodynamic feedbacks.

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An OpenFOAM solver for computing suspended particles in water currents

Olsen

Kadia

Pummer

et al. 2023

Journal of Hydroinformatics

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A new OpenFOAM solver has been developed for computing the spatial variation of particle concentrations in flowing water. The new solver was programmed in C ++ using OpenFOAM libraries, and the source code has been made openly available. The current article describes the coding of how the water flow and particle movements are computed. The solver is based on a Eulearian approach, where the particles are computed as concentrations in cells of a grid that resolves the computational domain. The Reynolds-averaged Navier–Stokes equations are solved by simpleFoam, using the k-ε turbulence model. The new solver uses a drift-flux approach to take the fall or rise velocity of the particles into account in a convection-diffusion equation. The model is therefore called sediDriftFoam. The results from the solver were tested on two cases with different types of particles. The first case was a sand trap with sand particles. The geometry was three-dimensional with a recirculation zone. The computed sediment concentrations in three vertical profiles compared well with earlier numerical studies and laboratory measurements. The second case was a straight channel flume with plastic particles that had a positive rise velocity. In this case, the results also compared well with the laboratory measurements.

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Particle-resolved simulation of antidunes in free-surface flows

Cited by 3 publications

References 22 publications

EcoGIS-Simulation Software for riverbed sediments modeling

EcoGIS-Simulation Software for riverbed sediments modeling

Antidune simulations using continuum‐based models

An OpenFOAM solver for computing suspended particles in water currents

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