Minimum requirements for predictive pore-network modeling of solute transport in micromodels

Mehmani, Yashar

doi:10.1016/j.advwatres.2017.07.014

Cited by 53 publications

(39 citation statements)

References 50 publications

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“…12). [276][277][278] Recently, PNMs have been used to model the electrochemical transport in electrodes and determine physical characteristics, such as the pore size distribution, permeability, porosity and electroactive surface area. 279 The robustness of PNM has afforded a platform for rapid parametric studies to determine physical insights into electrode microstructure on RFB performance.…”

Section: Quantification and Modelling Of Electrode Properties At Micrmentioning

confidence: 99%

Modelling of redox flow battery electrode processes at a range of length scales: a review

Chakrabarti

Kalamaras

Singh

et al. 2020

Sustainable Energy Fuels

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Section: Quantification and Modelling Of Electrode Properties At Micrmentioning

confidence: 99%

Modelling of redox flow battery electrode processes at a range of length scales: a review

Chakrabarti

Kalamaras

Singh

et al. 2020

Sustainable Energy Fuels

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“…Alternatively, pore network models (PNM) approximate the pore- to achieve orders of magnitude faster computational times than direct simulation methods (Raeini et al, 2015;Bultreys et al, 2016;Zhao et al, 2019), and therefore have the potential to run centimeter-scale sample domains. Pore network models have been used to study an array of processes in porous media such as solute and reactive transport (Bijeljic et al, 2004;Mehmani & Tchelepi, 2017), multiphase displacement behavior (Chen & Wilkinson, 1985;Lenormand et al, 1988;Idowu & Blunt, 2010;J. Li et al, 2017), diffusiondriven transport (De Chalendar et al, 2018), capillary pressure characteristic behavior (Bakke & Øren, 1997;Vogel et al, 2005;Silin & Patzek, 2006;Hussain et al, 2014), and relative permeability (M. Blunt & King, 1991;Jerauld & Salter, 1990; M. J.…”

Section: Introductionmentioning

confidence: 99%

Pore Network Model Predictions of Darcy‐Scale Multiphase Flow Heterogeneity Validated by Experiments

Zahasky

Jackson

Lin

et al. 2020

Water Resources Research

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“…For certain geometries, simple analytical expressions for g ij are available in the literature (Patzek and Silin 2001). Otherwise, numerical upscaling (Mehmani and Tchelepi 2017;Weishaupt et al 2019) may be used.…”

Section: Pore-network Modelmentioning

confidence: 99%

A Hybrid-Dimensional Coupled Pore-Network/Free-Flow Model Including Pore-Scale Slip and Its Application to a Micromodel Experiment

et al. 2020

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Modeling coupled systems of free flow adjacent to a porous medium by means of fully resolved Navier–Stokes equations is limited by the immense computational cost and is thus only feasible for relatively small domains. Coupled, hybrid-dimensional models can be much more efficient by simplifying the porous domain, e.g., in terms of a pore-network model. In this work, we present a coupled pore-network/free-flow model taking into account pore-scale slip at the local interfaces between free flow and the pores. We consider two-dimensional and three-dimensional setups and show that our proposed slip condition can significantly increase the coupled model’s accuracy: compared to fully resolved equidimensional numerical reference solutions, the normalized errors for velocity are reduced by a factor of more than five, depending on the flow configuration. A pore-scale slip parameter $$\beta _{{{{\rm pore}}}}$$ β pore required by the slip condition was determined numerically in a preprocessing step. We found a linear scaling behavior of $$\beta _{{{{\rm pore}}}}$$ β pore with the size of the interface pore body for three-dimensional and two-dimensional domains. The slip condition can thus be applied without incurring any run-time cost. In the last section of this work, we used the coupled model to recalculate a microfluidic experiment where we additionally exploited the flat structure of the micromodel which permits the use of a quasi-3D free-flow model. The extended coupled model is accurate and efficient.

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Minimum requirements for predictive pore-network modeling of solute transport in micromodels

Cited by 53 publications

References 50 publications

Modelling of redox flow battery electrode processes at a range of length scales: a review

Modelling of redox flow battery electrode processes at a range of length scales: a review

Pore Network Model Predictions of Darcy‐Scale Multiphase Flow Heterogeneity Validated by Experiments

A Hybrid-Dimensional Coupled Pore-Network/Free-Flow Model Including Pore-Scale Slip and Its Application to a Micromodel Experiment

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