A probabilistic description of the bed load sediment flux: 3. The particle velocity distribution and the diffusive flux

Furbish, David Jon; Roseberry, John C.; Schmeeckle, M. W.

doi:10.1029/2012jf002355

Cited by 43 publications

(131 citation statements)

References 26 publications

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“…We do not gloss over the importance of particle velocity, however, its calculation is more easily amenable to analysis when we focus on short timescales. On longer timescales, when particle paths are characterized by alternating mobile and resting phases, this analysis is more involved (Ganti et al 2010;Zhang et al 2012). In the former case, the central limit theorem applies and we expect that the arithmetic mean U n tends to a well-defined mean particle velocityū s .…”

Section: Stochastic Behaviour For a Fixed Control Volumementioning

confidence: 97%

“…In the former case, the central limit theorem applies and we expect that the arithmetic mean U n tends to a well-defined mean particle velocityū s . There are a number of models available for calculating the mean velocity of a single particle as a function of the flow velocity or shear stress (Wiberg & Smith 1985;Ancey et al 2002;Niño et al 2002;Chatanantavet et al 2013), as well as its statistical properties (Lajeunesse, Malverti & Charru 2010;Furbish, Roseberry & Schmeeckle 2012b). Therefore, for the sake of simplicity, we assume that the mean particle velocityū s (x, t;v, h) can be determined independently and is fully controlled by the water stream.…”

Section: Stochastic Behaviour For a Fixed Control Volumementioning

confidence: 99%

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A microstructural approach to bed load transport: mean behaviour and fluctuations of particle transport rates

2014

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This paper concerns a model of bed load transport, which describes the advection and dispersion of coarse particles carried by a turbulent water stream. The challenge is to develop a microstructural approach that, on the one hand, yields a parsimonious description of particle transport at the microscopic scale and, on the other hand, leads to averaged equations at the macroscopic scale that can be consistently interpreted in light of the continuum equations used in hydraulics. The cornerstone of the theory is the proper determination of the particle flux fluctuations. Apart from turbulence-induced noise, fluctuations in the particle transport rate are generated by particle exchanges with the bed consisting of particle entrainment and deposition. At the particle scale, the evolution of the number of moving particles can be described probabilistically using a coupled set of reaction-diffusion master equations. Theoretically, this is interesting but impractical, as solving the governing equations is fraught with difficulty. Using the Poisson representation, we show that these multivariate master equations can be converted into Fokker-Planck equations without any simplifying approximations. Thus, in the continuum limit, we end up with a Langevin-like stochastic partial differential equation that governs the time and space variations of the probability density function for the number of moving particles. For steady-state flow conditions and a fixed control volume, the probability distributions of the number of moving particles and the particle flux can be calculated analytically. Taking the average of the microscopic governing equations leads to an average mass conservation equation, which takes the form of the classic Exner equation under certain conditions carefully addressed in the paper. Analysis also highlights the specific part played by a process we refer to as collective entrainment, i.e. a nonlinear feedback process in particle entrainment. In the absence of collective entrainment the fluctuations in the number of moving particles are Poissonian, which implies that at the macroscopic scale they act as white noise that mediates bed evolution. In contrast, when collective entrainment occurs, large non-Poissonian fluctuations arise, with the important consequence that the evolution at the macroscopic scale may depart significantly that predicted by the averaged Exner equation. Comparison with experimental data gives satisfactory results for steady-state flows.

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Section: Stochastic Behaviour For a Fixed Control Volumementioning

confidence: 97%

Section: Stochastic Behaviour For a Fixed Control Volumementioning

confidence: 99%

A microstructural approach to bed load transport: mean behaviour and fluctuations of particle transport rates

2014

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“…And a computation of the local solid discharge with [2,3] first requires to extend the model to non-uniform flow conditions. Last, with a small diffusive term, the kinetic approach of [18][19][20][21]42] cannot improve on standard Exner model: it is not a new equation and it still requires empirical fitting. Contrary to the latter interpretation of Exner equation starting with a kinetic framework and ending with a fully deterministic closure at the hydrodynamic scale, our model lets the coupled hydrodynamic depend stochastically (through the coupling) on the random particles activity.…”

Section: A New Stochastic Exner Modelmentioning

confidence: 99%

“…In the series of papers [18][19][20][21]42], a kinetic approach is used in order to derive Exner equation, from the evolution equation of the probability density of particles possessing some "activity" γ at position x and time t, the time-derivative of that density supposedly being directly proportional to the time-derivative of the bed elevation. This yields a reinterpretation of Exner equation as a nonlinear advection-diffusion equation for the bed elevation, and consequently includes the possibility of a diffusive behaviour that is sometimes observed in experiments (depending on the flows and on the sampling-time of measures).…”

Section: A New Stochastic Exner Modelmentioning

confidence: 99%

Numerical simulation of the dynamics of sedimentary river beds with a stochastic Exner equation

Audusse¹,

Boyaval²,

Goutal³

et al. 2015

ESAIM: Proc.

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Abstract. At the scale of a river reach, the dynamics of the river bed is typically modelled by Exner equation (conservation of the solid mass) with an empirical solid flux of transported sediments, which is a simple deterministic algebraic formula function of i) the sediment physical characteristics (size and mass) and of ii) the averaged hydrodynamical description of the ambient water flow. This model has proved useful, in particular through numerical simulations, for hydraulic engineering purposes (like estimating the mass of sediments that is drained through an open dam). Though, the model is also coarse. And its applicability at various space and time scales remains a question of considerable interest for sedimentologists. In particular, physical experiments from the grain scale to the laboratory scale reveal important fluctuations of the solid flux in given hydrodynamical conditions. This work is a preliminary study of the coupling of a stochastic Exner equation with a hydrodynamical model for large scales. (Stochastic models with a probabilistic solid flux are currently being investigated, but most often only from the viewpoint of theoretical physics at the grain scale.) We introduce a new stochastic Exner model and discuss it using numerical simulations in an appropriate test case.Résumé. A l'échelle d'un bras de rivière, la dynamique du lit de la rivière est généralement modélisée par l'équation d'Exner (conservation de la masse solide) avec un flux solide empirique pour le transport de sédiments, flux défini par une formule algébrique et déterministe dépendant i) des caractéristiques physiques des sédiments (taille et masse) et ii) de la description hydraulique moyenne de l'écoulement local. Ce modèle s'est avéré utile, notammentà travers des simulations numériques, pour des applications en ingénierie hydraulique (par exemple, estimation de la masse de sédiments mobilisée lors d'une vidange de barrage). Néanmoins, le modèle estégalement grossier. Et son utilisation pour deséchelles de temps et d'espace variées reste une question d'un intérêt considérable pour les sédimentologues. En particulier, les expériences physiques allant de l'échelle du grainà celle du laboratoire révèlent d'importantes fluctuations du flux solide sous des conditions hydrodynamiques données.Ce travail est uneétude préliminaire du couplage d'uneéquation d'Exner stochastique avec un modèle hydrodynamique pour les grandeséchelles. (Des modèles stochastiques prenant en compte un flux solide probabiliste sont actuellementétudiés, mais le plus souvent seulement du point de vue de la physique théoriqueà l'échelle du grain.) On introduit un nouveau modèle d'Exner stochastique possible puis on le discuteà l'aide de simulations numériquesà travers un cas test approprié.

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“…The probabilistic definition has been further applied to describe the bed load sediment flux, e.g. particle velocity distribution, particle motions (Furbish et al, 2012a;Furbish et al, 2012b;Furbish et al, 2012c;Roseberry et al, 2012).…”

Section: Sediment Transport Modelsmentioning

confidence: 99%

Swash zone boundary conditions and direct bed shear stress measurements over loose sediment beds

Zhu¹

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The hydrodynamic and bed boundary conditions in the swash zone are investigated through laboratory, field and numerical experiments. The swash hydrodynamics induced by monochromatic waves were numerically investigated by using the CoulWave model. The correlation between the swash flow asymmetry parameter k and offshore wave parameters (e.g. wave height H, wave period T and Iribarren number ξ) was examined. The computed magnitude of k agrees with the results (-1, 1.5) from remote sensing field data but falls in a relatively narrow range of [0.68, 0.89]. A low correlation was observed between k and wave parameters examined in the present study.The role of the hydraulic resistance in the swash zone has been investigated by comparisons with an existing analytical solution (Shen and Meyer, 1963) and a semi-analytical swash hydrodynamics model (Guard and Baldock, 2007). The characteristic form equations incorporated with a Chézy type friction term were solved by the finite difference mid-point method. The swash hydrodynamics appear to be damped in the presence of the friction term and the resolved shoreline motions were retarded as well. However, the swash asymmetry (k) is not significantly affected by the friction term.

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A probabilistic description of the bed load sediment flux: 3. The particle velocity distribution and the diffusive flux

Cited by 43 publications

References 26 publications

A microstructural approach to bed load transport: mean behaviour and fluctuations of particle transport rates

A microstructural approach to bed load transport: mean behaviour and fluctuations of particle transport rates

Numerical simulation of the dynamics of sedimentary river beds with a stochastic Exner equation

Swash zone boundary conditions and direct bed shear stress measurements over loose sediment beds

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