Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix

Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix

Long-term evolution of permeability and tortuosity due to porosity changes evoked by reactivity of aqueous solutions is of paramount importance for predicting water-rock interaction. This challenge is best tackled by introducing reactive transport modelling on the pore-scale, where the modeling doma...

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Main Authors: Hinz Christian, Enzmann Frieder, Kersten Michael
Format: Article
Language:English
Published: EDP Sciences 2019-01-01
Series:E3S Web of Conferences
Online Access:https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_05010.pdf
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spelling doaj-f92bfa2273f94053858a3b655eac2edb2021-03-02T09:19:52ZengEDP SciencesE3S Web of Conferences2267-12422019-01-01980501010.1051/e3sconf/20199805010e3sconf_wri-162018_05010Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrixHinz ChristianEnzmann Frieder0Kersten Michael1Geosciences Institute, Johannes Gutenberg-UniversityGeosciences Institute, Johannes Gutenberg-UniversityLong-term evolution of permeability and tortuosity due to porosity changes evoked by reactivity of aqueous solutions is of paramount importance for predicting water-rock interaction. This challenge is best tackled by introducing reactive transport modelling on the pore-scale, where the modeling domain is a high-resolution tomographic image of the porous media. We suggest to use a voxel based Navier-Stokes-Brinkman solver in a finite volume formulation coupled to the thermodynamic equilibrium code PhreeqC. High-performance parallelized computations using this coupled numerical reactive transport solver are performed directly on the voxel grid of the segmented micro-CT scans. Retreat of the calcite cement in a sandstone matrix due to dissolution reactions can be directly visualized by digital rock physics experiments.https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_05010.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Hinz Christian
Enzmann Frieder
Kersten Michael
spellingShingle Hinz Christian
Enzmann Frieder
Kersten Michael
Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
E3S Web of Conferences
author_facet Hinz Christian
Enzmann Frieder
Kersten Michael
author_sort Hinz Christian
title Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
title_short Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
title_full Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
title_fullStr Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
title_full_unstemmed Pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
title_sort pore scale modelling of calcite cement dissolution in a reservoir sandstone matrix
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2019-01-01
description Long-term evolution of permeability and tortuosity due to porosity changes evoked by reactivity of aqueous solutions is of paramount importance for predicting water-rock interaction. This challenge is best tackled by introducing reactive transport modelling on the pore-scale, where the modeling domain is a high-resolution tomographic image of the porous media. We suggest to use a voxel based Navier-Stokes-Brinkman solver in a finite volume formulation coupled to the thermodynamic equilibrium code PhreeqC. High-performance parallelized computations using this coupled numerical reactive transport solver are performed directly on the voxel grid of the segmented micro-CT scans. Retreat of the calcite cement in a sandstone matrix due to dissolution reactions can be directly visualized by digital rock physics experiments.
url https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_05010.pdf
work_keys_str_mv AT hinzchristian porescalemodellingofcalcitecementdissolutioninareservoirsandstonematrix
AT enzmannfrieder porescalemodellingofcalcitecementdissolutioninareservoirsandstonematrix
AT kerstenmichael porescalemodellingofcalcitecementdissolutioninareservoirsandstonematrix
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