On the validity of effective formulations for transport through heterogeneous porous media

Dreuzy, J.-R. de; Carrera, Jesús

doi:10.5194/hess-20-1319-2016

Cited by 18 publications

(18 citation statements)

References 60 publications

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“…Many approaches exist for modeling effective upscaled transport in highly heterogeneous porous media, e.g., multi-rate mass transfer models [41], fractional advection-dispersion equations [10], and continuous time random walks [42]. In this paper, we will focus on one particular model, the Spatial Markov model (SMM).…”

Section: Introductionmentioning

confidence: 99%

Upscaling Mixing in Highly Heterogeneous Porous Media via a Spatial Markov Model

Wright

Sund

Richter

et al. 2018

Water

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In this work, we develop a novel Lagrangian model able to predict solute mixing in heterogeneous porous media. The Spatial Markov model has previously been used to predict effective mean conservative transport in flows through heterogeneous porous media. In predicting effective measures of mixing on larger scales, knowledge of only the mean transport is insufficient. Mixing is a small scale process driven by diffusion and the deformation of a plume by a non-uniform flow. In order to capture these small scale processes that are associated with mixing, the upscaled Spatial Markov model must be extended in such a way that it can adequately represent fluctuations in concentration. To address this problem, we develop downscaling procedures within the upscaled model to predict measures of mixing and dilution of a solute moving through an idealized heterogeneous porous medium. The upscaled model results are compared to measurements from a fully resolved simulation and found to be in good agreement.

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Section: Introductionmentioning

confidence: 99%

Upscaling Mixing in Highly Heterogeneous Porous Media via a Spatial Markov Model

Wright

Sund

Richter

et al. 2018

Water

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“…where c is the solute concentration, t is time, and D m is the molecular diffusion coefficient. The velocity vector in Equation 12is from the flow field based on solution of Equations (10) and (11). It is assumed that the initial concentrations were given by:…”

Section: Computational Fluid Dynamics (Cfd) Simulations Of the Flow Fmentioning

confidence: 99%

“…Mixing can be described by the SDR that is a global mixing measure based on the integral of concentration gradients. Recently, several studies have focused on the SDR evolution and scaling properties during solute transport in porous media [7,10,13,21,27,31,32,46]. However, all of those studies on SDR were restricted to porous media.…”

Section: Mixing: Scalar Dissipation Rate (Sdr)mentioning

confidence: 99%

“…Characterizing the spreading and mixing processes of conservative solute through the fractures is very important for the understanding of reaction rates and mass transport rates associated with nuclear waste disposal, enhanced oil recovery, and bioremediation [1][2][3][4][5][6]. Although, in recent decades, many studies have provided new insights into the mechanisms and properties of mixing processes in homogeneous and heterogeneous porous media [7][8][9][10][11][12][13][14][15][16][17], to date, little attention has been focused on mixing behavior in fractures.…”

Section: Introductionmentioning

confidence: 99%

“…This new decomposition of mixing showed a generic characterization and could offer new ways to establish a transport equation with consideration of both advection, spreading, and mixing. A comparison of different transport models can be found in [10]. A series of analytical solutions for the SDR was derived in non-conservative transport systems by Engdahl, Ginn, and Fogg [32].…”

Section: Introductionmentioning

confidence: 99%

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Temporal Mixing Behavior of Conservative Solute Transport through 2D Self-Affine Fractures

et al. 2018

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In this work, the influence of the Hurst exponent and Peclet number (Pe) on the temporal mixing behavior of a conservative solute in the self-affine fractures with variable-aperture fracture and constant-aperture distributions were investigated. The mixing was quantified by the scalar dissipation rate (SDR) in fractures. The investigation shows that the variable-aperture distribution leads to local fluctuation of the temporal evolution of the SDR, whereas the temporal evolution of the SDR in the constant-aperture fractures is smoothly decreasing as a power-law function of time. The Peclet number plays a dominant role in the temporal evolution of mixing in both variable-aperture and constant-aperture fractures. In the constant-aperture fracture, the influence of Hurst exponent on the temporal evolution of the SDR becomes negligible when the Peclet number is relatively small. The longitudinal SDR can be related to the global SDR in the constant-aperture fracture when the Peclet number is relatively small. As the Peclet number increases the longitudinal SDR overpredicts the global SDR. In the variable-aperture fractures, predicting the global SDR from the longitudinal SDR is inappropriate due to the non-monotonic increase of the longitudinal concentration second moment, which results in a physically meaningless SDR.

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Introduction

Dou,

Zhou,

Wang

et al. 2024

Mass Transfer Dynamics of Contaminants in Fractured Media

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On the validity of effective formulations for transport through heterogeneous porous media

Cited by 18 publications

References 60 publications

Upscaling Mixing in Highly Heterogeneous Porous Media via a Spatial Markov Model

Upscaling Mixing in Highly Heterogeneous Porous Media via a Spatial Markov Model

Temporal Mixing Behavior of Conservative Solute Transport through 2D Self-Affine Fractures

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