Particle diffusion in complex nanoscale pore networks

Dirk Müter; Henning Osholm Sørensen; H. Bock; Susan Louise Svane Stipp

doi:10.1021/jp5117867

Particle diffusion in complex nanoscale pore networks

Dirk Müter^*, Henning Osholm Sørensen, H. Bock, Susan Louise Svane Stipp

^*Corresponding author for this work

Department of Chemistry

12 Citations (Scopus)

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Abstract

We studied the diffusion of particles in the highly irregular pore networks of chalk, a very fine-grained rock, by combining three-dimensional X-ray imaging and dissipative particle dynamics (DPD) simulations. X-ray imaging data were collected at 25 nm voxel dimension for two chalk samples with very different porosities (4% and 26%). The three-dimensional pore systems derived from the tomograms were imported into DPD simulations and filled with spherical particles of variable diameter and with an optional attractive interaction to the pore surfaces. We found that diffusion significantly decreased to as much as 60% when particle size increased from 1% to 35% of the average pore diameter. When particles were attracted to the pore surfaces, even very small particles, diffusion was drastically inhibited, by as much as a factor of 100. Thus, the size of particles and their interaction with the pore surface strongly influence particle mobility and must be taken into account for predicting permeability in nanoporous rocks from primary petrophysical parameters such as surface area, porosity, and tortuosity.

Original language	English
Journal	Journal of Physical Chemistry C
Volume	119
Issue number	19
Pages (from-to)	10329-10335
Number of pages	7
ISSN	1932-7447
DOIs	https://doi.org/10.1021/jp5117867
Publication status	Published - 2015

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Mueter_Particle Diffusion in Complex Nanoscale Pore Networks_ver251114Accepted author manuscript, 1.17 MBLicence: Other

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title = "Particle diffusion in complex nanoscale pore networks",

abstract = "We studied the diffusion of particles in the highly irregular pore networks of chalk, a very fine-grained rock, by combining three-dimensional X-ray imaging and dissipative particle dynamics (DPD) simulations. X-ray imaging data were collected at 25 nm voxel dimension for two chalk samples with very different porosities (4% and 26%). The three-dimensional pore systems derived from the tomograms were imported into DPD simulations and filled with spherical particles of variable diameter and with an optional attractive interaction to the pore surfaces. We found that diffusion significantly decreased to as much as 60% when particle size increased from 1% to 35% of the average pore diameter. When particles were attracted to the pore surfaces, even very small particles, diffusion was drastically inhibited, by as much as a factor of 100. Thus, the size of particles and their interaction with the pore surface strongly influence particle mobility and must be taken into account for predicting permeability in nanoporous rocks from primary petrophysical parameters such as surface area, porosity, and tortuosity.",

author = "Dirk M{\"u}ter and S{\o}rensen, {Henning Osholm} and H. Bock and Stipp, {Susan Louise Svane}",

year = "2015",

doi = "10.1021/jp5117867",

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volume = "119",

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journal = "The Journal of Physical Chemistry Part C",

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TY - JOUR

T1 - Particle diffusion in complex nanoscale pore networks

AU - Müter, Dirk

AU - Sørensen, Henning Osholm

AU - Bock, H.

AU - Stipp, Susan Louise Svane

PY - 2015

Y1 - 2015

N2 - We studied the diffusion of particles in the highly irregular pore networks of chalk, a very fine-grained rock, by combining three-dimensional X-ray imaging and dissipative particle dynamics (DPD) simulations. X-ray imaging data were collected at 25 nm voxel dimension for two chalk samples with very different porosities (4% and 26%). The three-dimensional pore systems derived from the tomograms were imported into DPD simulations and filled with spherical particles of variable diameter and with an optional attractive interaction to the pore surfaces. We found that diffusion significantly decreased to as much as 60% when particle size increased from 1% to 35% of the average pore diameter. When particles were attracted to the pore surfaces, even very small particles, diffusion was drastically inhibited, by as much as a factor of 100. Thus, the size of particles and their interaction with the pore surface strongly influence particle mobility and must be taken into account for predicting permeability in nanoporous rocks from primary petrophysical parameters such as surface area, porosity, and tortuosity.

AB - We studied the diffusion of particles in the highly irregular pore networks of chalk, a very fine-grained rock, by combining three-dimensional X-ray imaging and dissipative particle dynamics (DPD) simulations. X-ray imaging data were collected at 25 nm voxel dimension for two chalk samples with very different porosities (4% and 26%). The three-dimensional pore systems derived from the tomograms were imported into DPD simulations and filled with spherical particles of variable diameter and with an optional attractive interaction to the pore surfaces. We found that diffusion significantly decreased to as much as 60% when particle size increased from 1% to 35% of the average pore diameter. When particles were attracted to the pore surfaces, even very small particles, diffusion was drastically inhibited, by as much as a factor of 100. Thus, the size of particles and their interaction with the pore surface strongly influence particle mobility and must be taken into account for predicting permeability in nanoporous rocks from primary petrophysical parameters such as surface area, porosity, and tortuosity.

U2 - 10.1021/jp5117867

DO - 10.1021/jp5117867

M3 - Journal article

AN - SCOPUS:84929359233

SN - 1932-7447

VL - 119

SP - 10329

EP - 10335

JO - The Journal of Physical Chemistry Part C

JF - The Journal of Physical Chemistry Part C

IS - 19

ER -

Particle diffusion in complex nanoscale pore networks

Abstract

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