A semi-Lagrangian method for the direct numerical simulation of crystallization and precipitation at the pore scale

Sarah Perez; Jean-Matthieu Etancelin; Philippe Poncet

doi:10.3389/feart.2025.1493305

A semi-Lagrangian method for the direct numerical simulation of crystallization and precipitation at the pore scale

Sarah Perez, Jean-Matthieu Etancelin, Philippe Poncet^*

^*Corresponding author for this work

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Abstract

This article introduces a new efficient particle method for the numerical simulation of crystallization and precipitation at the pore scale of real rock geometries extracted by X-Ray tomography. It is based on the coupling between superficial velocity models of porous media, Lagrangian description of chemistry using Transition-State-Theory, involving underlying grids. Its ability to successfully compute dissolution process has been established in the past, and is presently generalized to precipitation and crystallization by means of adsorption modeling. Numerical simulations of mineral CO 2 trapping are provided, showing evidence of clogging/non-clogging regimes, and one of the main results is the introduction of a new non-dimensional number needed for this characterization.

Original language	English
Article number	1493305
Journal	Frontiers in Earth Science
Volume	13
DOIs	https://doi.org/10.3389/feart.2025.1493305
Publication status	Published - 7 Mar 2025

Keywords

CO2 storage
Lagrangian methods
clogging
crystallization
digital rock physics (DRP)
mineral trapping
precipitation
superficial velocity

ASJC Scopus subject areas

General Earth and Planetary Sciences

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abstract = "This article introduces a new efficient particle method for the numerical simulation of crystallization and precipitation at the pore scale of real rock geometries extracted by X-Ray tomography. It is based on the coupling between superficial velocity models of porous media, Lagrangian description of chemistry using Transition-State-Theory, involving underlying grids. Its ability to successfully compute dissolution process has been established in the past, and is presently generalized to precipitation and crystallization by means of adsorption modeling. Numerical simulations of mineral CO 2 trapping are provided, showing evidence of clogging/non-clogging regimes, and one of the main results is the introduction of a new non-dimensional number needed for this characterization.",

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AB - This article introduces a new efficient particle method for the numerical simulation of crystallization and precipitation at the pore scale of real rock geometries extracted by X-Ray tomography. It is based on the coupling between superficial velocity models of porous media, Lagrangian description of chemistry using Transition-State-Theory, involving underlying grids. Its ability to successfully compute dissolution process has been established in the past, and is presently generalized to precipitation and crystallization by means of adsorption modeling. Numerical simulations of mineral CO 2 trapping are provided, showing evidence of clogging/non-clogging regimes, and one of the main results is the introduction of a new non-dimensional number needed for this characterization.

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A semi-Lagrangian method for the direct numerical simulation of crystallization and precipitation at the pore scale

Abstract

Keywords

ASJC Scopus subject areas

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