Particle-tracking simulation of fractional diffusion-reaction processes

Zhang, Yong; Papelis, Charalambos

doi:10.1103/physreve.84.066704

Cited by 22 publications

(13 citation statements)

References 47 publications

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“…Second, how will anomalous diffusion affect bimolecular reactions in a sand column? To address this question, we develop particle‐based models by combining previously developed Lagrangian approaches [ Zhang and Papelis , ; Zhang et al ., ] to quantify reactions coupled with anomalous diffusion. Finally, can a predictive physical model be built for reactive transport in a deceptively simple “homogeneous” medium?…”

Section: Introductionmentioning

confidence: 99%

Improved understanding of bimolecular reactions in deceptively simple homogeneous media: From laboratory experiments to Lagrangian quantification

et al. 2014

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Medium heterogeneity affects reaction kinetics by controlling the mixing of reactant particles, but the linkage between medium properties and reaction kinetics is difficult to build, even for simple, relatively homogeneous media. This study aims to explore the dynamics of bimolecular reactions, aniline 1 1,2-naphthoquinone-4-sulfonic acid ! 1,2-naphthoquinone-4-aminobenzene, in relatively homogeneous flow cells. Laboratory experiments were conducted to monitor the transport of both conservative and reactive tracers through columns packed with silica sand of specific diameters. The measured tracer breakthrough curves exhibit subdiffusive behavior with a late-time tail becoming more pronounced with decreasing sand size, probably due to the segregated flow regions formed more easily in columns packed with smaller size sand. Numerical analysis using a novel Lagrangian model shows that subdiffusion has a twofold effect on bimolecular reactions. While subdiffusion enhances the power-law growth rate of product mass by prolonging the exposure of reactant particles in the depletion zone, the global reaction rate is constrained because subdiffusion constrains the mobility of reactant particles. Reactive kinetics in deceptively simple homogeneous media is therefore controlled by subdiffusion, which is sensitive to the dimensions of packed sand.

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Section: Introductionmentioning

confidence: 99%

Improved understanding of bimolecular reactions in deceptively simple homogeneous media: From laboratory experiments to Lagrangian quantification

et al. 2014

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“…Without loss of generality we assume unit activity coefficients. This type of reaction has been studied experimentally and theoretically because of its simplicity and dependence on local mixing (e.g., [32,33,34,35,36,37,38]). The plates are separated by aperture b = 1 mm, and the molecular diffusion coefficient is 10 −3 mm 2 /s.…”

Section: Hagen-poiseuille Flowmentioning

confidence: 99%

On the separate treatment of mixing and spreading by the reactive-particle-tracking algorithm: An example of accurate upscaling of reactive Poiseuille flow

Benson

Pankavich

Bolster

2019

Advances in Water Resources

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The Eulerian advection-dispersion-reaction equation (ADRE) suffers the well-known scaleeffect of reduced apparent reaction rates between chemically dissimilar fluids at larger scales (or dimensional averaging). The dispersion tensor in the ADRE must equally and simultaneously account for both solute mixing and spreading. Recent reactive-particletracking (RPT) algorithms can, by separate mechanisms, simulate 1) smaller-scale mixing by inter-particle mass transfer, and 2) mass spreading by traditional random walks. To test the supposition that the RPT can accurately track these separate mechanisms, we upscale reactive transport in Hagen-Poiseuille flow between two plates. The simple upscaled 1-D RPT model with one velocity value, an upscaled Taylor macro-dispersivity, and the local molecular diffusion coefficient matches the results obtained from a detailed 2-D model with fully described velocity and diffusion. Both models use the same thermodynamic reaction rate, because the rate is not forced to absorb the loss of information upon upscaling. Analytic and semi-analytic upscaling is also performed using volume averaging and ensemble streamtube techniques. Volume averaging does not perform as well as the RPT, while ensemble streamtubes (using an effective dispersion coefficient along with macro-dispersion) perform almost exactly the same as RPT.

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“…First, the vector Langevin approach developed by Zhang et al [51] can be used to approximate the vector transport model (2), where the combination of the mixing measure M and the eigenvectors of H defines the multi-dimensional jumps of tracer particles. Numerical examples of this step can be found in Zhang and Papelis [54]. The second step is to solve the immobile process (5), by calculating and assigning the random waiting time for each particle using a wellvalidated time Langevin approach [52].…”

Section: The Tempered Fractional-derivative Modelmentioning

confidence: 99%

Fractional dynamics of tracer transport in fractured media from local to regional scales

et al. 2013

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Abstract:Tracer transport through fractured media exhibits concurrent direction-dependent super-diffusive spreading along high-permeability fractures and sub-diffusion caused by mass transfer between fractures and the rock matrix. The resultant complex dynamics challenge the applicability of conventional physical models based on Fick's law. This study proposes a multi-scaling tempered fractional-derivative (TFD) model to explore fractional dynamics for tracer transport in fractured media. Applications show that the TFD model can capture anomalous transport observed in small-scale single fractures, intermediate-scale fractured aquifers, and two-dimensional large-scale discrete fracture networks. Tracer transport in fractured media from local (0.255-meter long) to regional (400-meter long) scales therefore can be quantified by a general fractional-derivative model. Fractional dynamics in fractured media can be scale dependent, owning to 1) the finite length of fractures that constrains the large displacement of tracers, and 2) the increasing mass exchange capacity along the travel path that enhances sub-diffusion. PACS

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Particle-tracking simulation of fractional diffusion-reaction processes

Cited by 22 publications

References 47 publications

Improved understanding of bimolecular reactions in deceptively simple homogeneous media: From laboratory experiments to Lagrangian quantification

Improved understanding of bimolecular reactions in deceptively simple homogeneous media: From laboratory experiments to Lagrangian quantification

On the separate treatment of mixing and spreading by the reactive-particle-tracking algorithm: An example of accurate upscaling of reactive Poiseuille flow

Fractional dynamics of tracer transport in fractured media from local to regional scales

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