A theoretical framework for modeling dilution enhancement of non-reactive solutes in heterogeneous porous media

A theoretical framework for modeling dilution enhancement of non-reactive solutes in heterogeneous porous media

Spatial heterogeneity of the hydraulic properties of geological porous formations leads to erratically shaped solute clouds, thus increasing the edge area of the solute body and augmenting the dilution rate. In this study, we provide a theoretical framework to quantify dilution of a non-reactive sol...

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Veröffentlicht in:Journal of contaminant hydrology 2015-04, Vol.175-176, p.72-83
Hauptverfasser: de Barros, F.P.J., Fiori, A., Boso, F., Bellin, A.
Format: Artikel
Sprache:eng
Schlagworte:
Anisotropy
Aquifer heterogeneity
Clouds
Computational fluid dynamics
Contaminant dilution
Dilution
Fluid flow
Groundwater
Heterogeneity
Hydraulics
Marine
Mathematical models
Mixing
Models, Theoretical
Porosity
Porous media
Solutions - chemistry
Stochastic hydrogeology
Time Factors
Water Movements
Water Pollutants, Chemical - chemistry
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container_end_page 83
container_issue
container_start_page 72
container_title Journal of contaminant hydrology
container_volume 175-176
creator de Barros, F.P.J.
Fiori, A.
Boso, F.
Bellin, A.
description Spatial heterogeneity of the hydraulic properties of geological porous formations leads to erratically shaped solute clouds, thus increasing the edge area of the solute body and augmenting the dilution rate. In this study, we provide a theoretical framework to quantify dilution of a non-reactive solute within a steady state flow as affected by the spatial variability of the hydraulic conductivity. Embracing the Lagrangian concentration framework, we obtain explicit semi-analytical expressions for the dilution index as a function of the structural parameters of the random hydraulic conductivity field, under the assumptions of uniform-in-the-average flow, small injection source and weak-to-mild heterogeneity. Results show how the dilution enhancement of the solute cloud is strongly dependent on both the statistical anisotropy ratio and the heterogeneity level of the porous medium. The explicit semi-analytical solution also captures the temporal evolution of the dilution rate; for the early- and late-time limits, the proposed solution recovers previous results from the literature, while at intermediate times it reflects the increasing interplay between large-scale advection and local-scale dispersion. The performance of the theoretical framework is verified with high resolution numerical results and successfully tested against the Cape Cod field data. •Semi-analytical solution for the dilution index in a heterogeneous aquifer•Quantifies dilution enhancement due to heterogeneity•Solution is compared with high resolution numerical simulations•Good comparison with field data
doi_str_mv 10.1016/j.jconhyd.2015.01.004
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subjects Anisotropy
Aquifer heterogeneity
Clouds
Computational fluid dynamics
Contaminant dilution
Dilution
Fluid flow
Groundwater
Heterogeneity
Hydraulics
Marine
Mathematical models
Mixing
Models, Theoretical
Porosity
Porous media
Solutions - chemistry
Stochastic hydrogeology
Time Factors
Water Movements
Water Pollutants, Chemical - chemistry
title A theoretical framework for modeling dilution enhancement of non-reactive solutes in heterogeneous porous media
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