On the importance of diffusion and compound-specific mixing for groundwater transport: An investigation from pore to field scale

Massimo Rolle, Gabriele Chiogna, David L. Hochstetler, Peter K. Kitanidis

Research output: Contribution to journalJournal articleResearchpeer-review

Abstract

Mixing processes significantly affect and limit contaminant transport and transformation rates in the subsurface. The correct quantification of mixing in groundwater systems must account for diffusion, local-scale dispersion and the flow variability in heterogeneous flow fields (e.g., flow-focusing in high-conductivity and de-focusing in low-conductivity zones). Recent results of multitracer laboratory experiments revealed the significant effect of compound-specific diffusive properties on the physical displacement of dissolved species across a representative range of groundwater flow velocities. The goal of this study is to investigate the role of diffusion and compound-specific mixing for solute transport across a range of scales including: (i) pore-scale (similar to 10(-2) m), (ii) laboratory bench-scale (similar to 10(0) m) and (iii) field-scale (similar to 10(2) m). We investigate both conservative and mixing-controlled reactive transport using pore-scale modeling, flow-through laboratory experiments and simulations, and field-scale numerical modeling of complex heterogeneous hydraulic conductivity fields with statistical properties similar to the ones reported for the extensively investigated Borden aquifer (Ontario, Canada) and Columbus aquifer (Mississippi, USA, also known as MADE site). We consider different steady-state and transient transport scenarios. For the conservative cases we use as a metric of mixing the exponential of the Shannon entropy to quantify solute dilution either in a given volume (dilution index) or in a given solute flux (flux-related dilution index). The decrease in the mass and the mass-flux of the contaminant plumes is evaluated to quantify reactive mixing. The results show that diffusive processes, occurring at the small-scale of a pore channel, strongly affect conservative and reactive solute transport at larger macroscopic scales. The outcomes of our study illustrate the need to consider and properly account for compound-specific diffusion and mixing limitations in order to accurately describe and predict conservative and reactive transport in porous media. (C) 2013 Elsevier B.V. All rights reserved.
Original languageEnglish
JournalJournal of Contaminant Hydrology
Volume153
Pages (from-to)51-68
Number of pages18
ISSN0169-7722
DOIs
Publication statusPublished - 2013
Externally publishedYes

Keywords

  • Water Science and Technology
  • Environmental Chemistry
  • Diffusion
  • Dilution index
  • Groundwater transport
  • Mixing
  • Numerical modeling
  • Contaminant transport
  • Diffusive properties
  • Groundwater system
  • Heterogeneous flow
  • Laboratory experiments
  • Statistical properties
  • Transient transport
  • Aquifers
  • Dilution
  • Experiments
  • Groundwater flow
  • Groundwater resources
  • Numerical models
  • Porous materials
  • Solute transport
  • ground water
  • accuracy assessment
  • aquifer
  • diffusion
  • dilution
  • experimental study
  • flow modeling
  • flow velocity
  • groundwater flow
  • hydraulic conductivity
  • laboratory method
  • numerical model
  • pollutant transport
  • porous medium
  • reactive transport
  • solute transport
  • article
  • field experiment
  • laboratory
  • mathematical model
  • mixing
  • physical phenomena
  • plume
  • pollution transport
  • porosity
  • priority journal
  • quantitative analysis
  • solute
  • steady state
  • transport kinetics
  • water contamination
  • water transport
  • Borden Aquifer
  • Canada
  • Columbus [Mississippi]
  • Mississippi
  • Ontario [Canada]
  • United States
  • Groundwater
  • Models, Theoretical
  • Porosity
  • Pseudomonas putida
  • Toluene
  • Water Movements
  • Water Pollutants, Chemical
  • 3FPU23BG52 Toluene
  • ENVIRONMENTAL
  • GEOSCIENCES,
  • WATER
  • HETEROGENEOUS POROUS-MEDIA
  • NATURAL GRADIENT EXPERIMENT
  • OIL-CONTAMINATED AQUIFER
  • LABORATORY EXPERIMENTS
  • HYDRAULIC CONDUCTIVITY
  • REACTIVE TRANSPORT
  • SOLUTE TRANSPORT
  • BACK-DIFFUSION
  • SAND AQUIFER
  • TRANSVERSE DISPERSION
  • compound-specific mixing role
  • diffusion role
  • groundwater
  • solute pollutant
  • 04500, Mathematical biology and statistical methods
  • 10515, Biophysics - Biocybernetics
  • 37015, Public health - Air, water and soil pollution
  • Computational Biology
  • dilution index laboratory techniques
  • field-scale numerical modeling mathematical and computer techniques
  • flow-through laboratory experiment laboratory techniques
  • laboratory bench-scale laboratory techniques
  • pore-scale modeling mathematical and computer techniques
  • Models and Simulations
  • Pollution Assessment Control and Management

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