VS2DRTI: Simulating Heat and Reactive Solute Transport in Variably Saturated Porous Media

Healy, Richard W.; Haile, S; Parkhurst, David L.; Charlton, Scott R.

doi:10.1111/gwat.12640

Cited by 8 publications

(6 citation statements)

References 25 publications

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“…Since 2015, the U.S. Geological Survey provides an API (PhreeqcRM) of the stand‐alone PHREEQC version (Parkhurst and Appelo 2013). The API substantially simplifies the integration of its components into other codes (Parkhurst and Wissmeier 2015) and several coupled codes that employ PhreeqcRM have been developed and presented since then (e.g., Healy et al 2018; Muniruzzaman and Rolle 2019). In muRT, the Phreeqc API has been included as an OpenFoam class that can be called whenever required.…”

Section: Numerical Implementationmentioning

confidence: 99%

“…Perhaps most significantly, the library does not allow to simulate unconfined groundwater flow systems, which is a severe limitation. In order to equip OpenFoam with suitable geochemical reaction capabilities, we followed the path of earlier coupling efforts in applying a sequential operator splitting approach (e.g., Walter et al 1994; Jacques et al 2012) and employed the USGS code PHREEQC as reaction simulator (e.g., Appelo and Willemsen 1987; Prommer et al 2003; Parkhurst et al 2010; De Sousa 2012; Healy et al 2018; Muniruzzaman and Rolle 2019; Lu et al 2022). Indeed, the popularity of coupling PHREEQC to flow/solute transport simulators has triggered the USGS to develop and release the PhreeqcRM API (available under GNU license), aimed at simplifying the mechanics of model coupling (Parkhurst and Wissmeier 2015).…”

Section: Introductionmentioning

confidence: 99%

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muFlowReacT: A Library to Solve Multiphase Multicomponent Reactive Transport on Unstructured Meshes

et al. 2023

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In this paper we present a new reactive transport code for the efficient simulation of groundwater quality problems. The new code couples the two previously existing tools OpenFoam and PhreeqcRM. The major objective of the development was to transfer and expand the capabilities of the MODFLOW/MT3DMS‐family of codes, especially their outstanding ability to suppress numerical dispersion, to a versatile and computationally efficient code for unstructured grids. Owing to the numerous, previously existing transport solvers contained in OpenFoam, the newly developed code achieves this objective and provides a solid basis for future expansions of the code capabilities. The flexibility of the OpenFoam framework is illustrated by the addition of diffusional processes for gaseous compounds in the unsaturated zone and the advection of gases (multiphase transport). The code capabilities and accuracy are illustrated through several examples: (1) a simple 2D case for conservative solute transport under saturated conditions, (2) a gas diffusion case with reactions in the unsaturated zone, (3) a hydrogeologically complex 3D reactive transport problem, and finally (4) the injection of CO2 into a deep aquifer with acidification being buffered by carbonate minerals.

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Section: Numerical Implementationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

muFlowReacT: A Library to Solve Multiphase Multicomponent Reactive Transport on Unstructured Meshes

et al. 2023

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“…In contrast, the multicomponent ionic transport in the free water and diffuse layer porosities is solved with a finite volume method in streamline-oriented grids following the approach of Cirpka et al (1999a,b). Furthermore, MMIT-Clay uses PHREEQC (Parkhurst and Appelo, 2013) as a reaction engine, utilizing the PhreeqcRM module (Parkhurst and Wissmeier, 2015), to allow flexibility to include all the chemical reactions that can be handled with PHREEQC (e.g., Jara et al 2017;Healy et al, 2018;Rolle et al 2018;Sprocati et al 2019;. Further details regarding numerical methods, implementation and solution approaches, and the verification of the code are available in Muniruzzaman and Rolle (2019).…”

Section: Governing Flow and Transport Equationsmentioning

confidence: 99%

Impact of diffuse layer processes on contaminant forward and back diffusion in heterogeneous sandy-clayey domains

Muniruzzaman

Rolle

2021

Journal of Contaminant Hydrology

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“…Furthermore, the presented multicomponent ionic transport code (MMIT-Clay) is coupled with PHREEQC (Parkhurst & Appelo, 2013), taking advantage of the capabilities of linking this geochemical simulator with transport codes (Charlton & Parkhurst, 2011;He et al, 2015;Nardi et al, 2014;Parkhurst & Wissmeier, 2015;Wissmeier & Barry, 2011;Muniruzzaman & Rolle, 2016). MMIT-Clay utilizes the PhreeqcRM module (Parkhurst & Wissmeier, 2015), which allows great flexibility and a multipurpose framework to access all the PHREEQC's reaction capabilities (e.g., Healy et al, 2018;Jara et al, 2017;Rolle et al, 2018). At the end of the advective and dispersive transport within a time step (Δt), the concentration vector of all the species (primary and secondary species from aqueous speciation) is passed to PhreeqcRM to perform reaction calculations (i.e., any other reactions excluding Donnan and/or interlayer processes), which are done by considering a batch reactor in each cell of the simulation domain containing user-defined reactive processes of interest.…”

Section: Modeling Approachmentioning

confidence: 99%

Multicomponent Ionic Transport Modeling in Physically and Electrostatically Heterogeneous Porous Media With PhreeqcRM Coupling for Geochemical Reactions

Muniruzzaman

Rolle

2019

Water Resources Research

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Low-permeability aquitards, such as clay layers and inclusions, are of utmost importance for contaminant transport in groundwater systems. Although most dissolved species, contaminants, and clay surfaces are charged, the role of electrostatic interactions in subsurface flow-through systems has not been extensively investigated. This study presents a two-dimensional multicomponent reactive transport investigation of diffusive/dispersive and electrostatic processes in homogeneous and heterogeneous clay systems. The proposed approach is based on multiple continua and is capable to accurately describe charge interactions during ionic transport in the free water, diffuse layer, and interlayer water of charged porous media. The diffuse layer composition is simulated by considering a mean electrostatic potential following Donnan approach, whereas the interlayer composition is calculated by adopting the Gaines-Thomas convention. Diffusive/dispersive fluxes within each subcontinuum (free water, diffuse layer, and interlayer) are calculated solving the Nernst-Planck equation while maintaining a net zero-charge flux. Furthermore, the multidimensional flow and transport model is coupled with the geochemical code PHREEQC, by utilizing the PhreeqcRM module, thus enabling great flexibility to access all PHREEQC's reaction capabilities. The code is benchmarked in 1-D systems against other software and previously published experimental data. Successively, reactive transport simulations are performed in 2-D clayey-sandy flowthrough domains with spatially variable physical and electrostatic properties at both laboratory and field scales. The results reveal that different properties of surface charge, diffuse layer, and Coulombic interactions impact the transport of charged species and lead to distinct spatial distribution of the ions in the different subcontinua and to significantly different breakthrough curves.

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VS2DRTI: Simulating Heat and Reactive Solute Transport in Variably Saturated Porous Media

Cited by 8 publications

References 25 publications

muFlowReacT: A Library to Solve Multiphase Multicomponent Reactive Transport on Unstructured Meshes

muFlowReacT: A Library to Solve Multiphase Multicomponent Reactive Transport on Unstructured Meshes

Impact of diffuse layer processes on contaminant forward and back diffusion in heterogeneous sandy-clayey domains

Multicomponent Ionic Transport Modeling in Physically and Electrostatically Heterogeneous Porous Media With PhreeqcRM Coupling for Geochemical Reactions

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