2015
DOI: 10.1016/j.advwatres.2015.09.028
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A random walk solution for modeling solute transport with network reactions and multi-rate mass transfer in heterogeneous systems: Impact of biofilms

Abstract: The interplay between the spatial variability of aquifer properties, mass transfer and chemical reactions often complicates reactive transport simulations. It is well documented that hydro-biochemical properties are ubiquitously heterogeneous and that rate-limited mass transfer typically leads to the conceptualization of an aquifer as a multi-porosity system. Within this context, chemical reactions taking place in mobile/immobile water regions can be substantially different between each other. This paper prese… Show more

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Cited by 24 publications
(32 citation statements)
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“…Since the method is meshless, truncation errors and artificial dispersion are negligible. The method can efficiently and effortlessly incorporate non‐Fickian transport [ Zhang and Benson , ] or multiple porosity systems [ Benson and Meerschaert , ; Henri and Fernàndez‐Garcia , ].…”
Section: Discussion: Do Stochastic Models Represent Somehow Reality? mentioning
confidence: 99%
“…Since the method is meshless, truncation errors and artificial dispersion are negligible. The method can efficiently and effortlessly incorporate non‐Fickian transport [ Zhang and Benson , ] or multiple porosity systems [ Benson and Meerschaert , ; Henri and Fernàndez‐Garcia , ].…”
Section: Discussion: Do Stochastic Models Represent Somehow Reality? mentioning
confidence: 99%
“…The solute transport problem was solved using the code RW3D that solves advection, dispersion and multirate mass transfer using the RWPT approach (Fernàndez‐Garcia et al, ; Henri & Fernàndez‐Garcia, ; Henri & Fernàndez‐Garcia, ; Salamon et al, ). The governing equation for advective‐dispersive transport is given by the following: italicθRct=()θboldDc()boldqc where q (L/T) is the groundwater flux, D (L 2 /T) is the dispersion tensor, θ (dimensionless) is the porosity, c (M/L 3 ) is the aqueous concentration, and R (dimensionless) is the retardation factor.…”
Section: Methodsmentioning
confidence: 99%
“…The solute transport problem was solved using the code RW3D that solves advection, dispersion and multirate mass transfer using the RWPT approach Henri & Fernàndez-Garcia, 2014;Henri & Fernàndez-Garcia, 2015;Salamon et al, 2006). The governing equation for advectivedispersive transport is given by the following:…”
Section: Solute Transport Modelmentioning
confidence: 99%
“…Solute transport was modeled using the code RW3D that solves advection, dispersion, and MRMT using the random walk particle tracking approach (Fernàndez-Garcia et al, 2005;Henri & Fernàndez-Garcia, 2014;Henri & Fernàndez-Garcia, 2015;Salamon et al, 2006). Longitudinal, transverse, and vertical dispersivities representing grid-scale dispersion were set to 1.0, 0.1, and 0.01 m, respectively.…”
Section: Groundwater Flow and Solute Transport Modelsmentioning
confidence: 99%