4D microvelocimetry reveals multiphase flow field perturbations in porous media

Tom Bultreys; Sharon Ellman; Christian M. Schlepütz; Matthieu N. Boone; Gülce Kalyoncu Pakkaner; Shan Wang; Mostafa Borji; Stefanie Van Offenwert; Niloofar Moazami Goudarzi; Wannes Goethals; Chandra Widyananda Winardhi; Veerle Cnudde

doi:10.1073/pnas.2316723121

4D microvelocimetry reveals multiphase flow field perturbations in porous media

Tom Bultreys
, Sharon Ellman
, Christian M. Schlepütz
, Matthieu N. Boone
, Gülce Kalyoncu Pakkaner
, Shan Wang
, Mostafa Borji
, Stefanie Van Offenwert
, Niloofar Moazami Goudarzi
, Wannes Goethals
, Chandra Widyananda Winardhi
, Veerle Cnudde

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Many environmental and industrial processes depend on how fluids displace each other in porous materials. However, the flow dynamics that govern this process are still poorly understood, hampered by the lack of methods to measure flows in optically opaque, microscopic geometries. We introduce a 4D microvelocimetry method based on high-resolution X-ray computed tomography with fast imaging rates (up to 4 Hz). We use this to measure flow fields during unsteady-state drainage, injecting a viscous fluid into rock and filter samples. This provides experimental insight into the nonequilibrium energy dynamics of this process. We show that fluid displacements convert surface energy into kinetic energy. The latter corresponds to velocity perturbations in the pore-scale flow field behind the invading fluid front, reaching local velocities more than 40 times faster than the constant pump rate. The characteristic length scale of these perturbations exceeds the characteristic pore size by more than an order of magnitude. These flow field observations suggest that nonlocal dynamic effects may be long-ranged even at low capillary numbers, impacting the local viscous-capillary force balance and the representative elementary volume. Furthermore, the velocity perturbations can enhance unsaturated dispersive mixing and colloid transport and yet, are not accounted for in current models. Overall, this work shows that 4D X-ray velocimetry opens the way to solve long-standing fundamental questions regarding flow and transport in porous materials, underlying models of, e.g., groundwater pollution remediation and subsurface storage of CO2 and hydrogen.

Original language	English
Article number	e2316723121
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	121
Issue number	12
DOIs	https://doi.org/10.1073/pnas.2316723121
Publication status	Published - 13 Mar 2024

Bibliographical note

Publisher Copyright:
Copyright © 2024 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

Funding

ACKNOWLEDGMENTS.Dr.Steffen Berg is acknowledged for helpful discussions on Haines jump dynamics. T.B. acknowledges funding from the European Union (ERC StartingGrant,FLOWSCOPY,101116228)andfromtheResearchFoundation-Flanders (FWO,senior research fellowship 12X0922N).S.E.is a PhD Fellow with the FWO and acknowledges its support under grant 1182822N.We acknowledge partial funding from FWO under research projects G004820N and 3G036518.W.G.and N.M.G.are supported by the Ghent University Special Research Fund (BOFGOA20170007 and BOF.24Y.2018.0007.02, respectively). We acknowledge the Paul Scherrer Institut, Villigen,Switzerland for provision of synchrotron radiation beamtime at the TOMCAT beamline X02DA of the SLS (beam time proposal 20212066). Dr. Steffen Berg is acknowledged for helpful discussions on Haines jump dynamics. T.B. acknowledges funding from the European Union (ERC Starting Grant,FLOWSCOPY,101116228) and from the Research Foundation-Flanders (FWO, senior research fellowship 12X0922N). S.E. is a PhD Fellow with the FWO and acknowledges its support under grant 1182822N. We acknowledge partial funding from FWO under research projects G004820N and 3G036518. W.G. and N.M.G. are supported by the Ghent University Special Research Fund (BOFGOA20170007 and BOF.24Y.2018.0007.02, respectively). We acknowledge the Paul Scherrer Institut, Villigen, Switzerland for provision of synchrotron radiation beamtime at the TOMCAT beamline X02DA of the SLS (beam time proposal 20212066).

Funders	Funder number
European Resuscitation Council
European Commission
Fonds Wetenschappelijk Onderzoek	12X0922N, 1182822N, 3G036518, G004820N
Fonds Wetenschappelijk Onderzoek
Ghent University Special Research Fund	BOF.24Y.2018.0007.02, BOFGOA20170007, 20212066

Keywords

3D velocimetry
hydrogeology
multiphase flow
porous media

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Bultreys, T., Ellman, S., Schlepütz, C. M., Boone, M. N., Pakkaner, G. K., Wang, S., Borji, M., Van Offenwert, S., Moazami Goudarzi, N., Goethals, W., Winardhi, C. W., & Cnudde, V. (2024). 4D microvelocimetry reveals multiphase flow field perturbations in porous media. Proceedings of the National Academy of Sciences of the United States of America, 121(12), Article e2316723121. https://doi.org/10.1073/pnas.2316723121

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abstract = "Many environmental and industrial processes depend on how fluids displace each other in porous materials. However, the flow dynamics that govern this process are still poorly understood, hampered by the lack of methods to measure flows in optically opaque, microscopic geometries. We introduce a 4D microvelocimetry method based on high-resolution X-ray computed tomography with fast imaging rates (up to 4 Hz). We use this to measure flow fields during unsteady-state drainage, injecting a viscous fluid into rock and filter samples. This provides experimental insight into the nonequilibrium energy dynamics of this process. We show that fluid displacements convert surface energy into kinetic energy. The latter corresponds to velocity perturbations in the pore-scale flow field behind the invading fluid front, reaching local velocities more than 40 times faster than the constant pump rate. The characteristic length scale of these perturbations exceeds the characteristic pore size by more than an order of magnitude. These flow field observations suggest that nonlocal dynamic effects may be long-ranged even at low capillary numbers, impacting the local viscous-capillary force balance and the representative elementary volume. Furthermore, the velocity perturbations can enhance unsaturated dispersive mixing and colloid transport and yet, are not accounted for in current models. Overall, this work shows that 4D X-ray velocimetry opens the way to solve long-standing fundamental questions regarding flow and transport in porous materials, underlying models of, e.g., groundwater pollution remediation and subsurface storage of CO2 and hydrogen.",

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note = "Publisher Copyright: Copyright {\textcopyright} 2024 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).",

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Bultreys, T, Ellman, S, Schlepütz, CM, Boone, MN, Pakkaner, GK, Wang, S, Borji, M, Van Offenwert, S, Moazami Goudarzi, N, Goethals, W, Winardhi, CW & Cnudde, V 2024, '4D microvelocimetry reveals multiphase flow field perturbations in porous media', Proceedings of the National Academy of Sciences of the United States of America, vol. 121, no. 12, e2316723121. https://doi.org/10.1073/pnas.2316723121

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T1 - 4D microvelocimetry reveals multiphase flow field perturbations in porous media

AU - Bultreys, Tom

AU - Ellman, Sharon

AU - Schlepütz, Christian M.

AU - Boone, Matthieu N.

AU - Pakkaner, Gülce Kalyoncu

AU - Wang, Shan

AU - Borji, Mostafa

AU - Van Offenwert, Stefanie

AU - Moazami Goudarzi, Niloofar

AU - Goethals, Wannes

AU - Winardhi, Chandra Widyananda

AU - Cnudde, Veerle

N1 - Publisher Copyright: Copyright © 2024 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

PY - 2024/3/13

Y1 - 2024/3/13

N2 - Many environmental and industrial processes depend on how fluids displace each other in porous materials. However, the flow dynamics that govern this process are still poorly understood, hampered by the lack of methods to measure flows in optically opaque, microscopic geometries. We introduce a 4D microvelocimetry method based on high-resolution X-ray computed tomography with fast imaging rates (up to 4 Hz). We use this to measure flow fields during unsteady-state drainage, injecting a viscous fluid into rock and filter samples. This provides experimental insight into the nonequilibrium energy dynamics of this process. We show that fluid displacements convert surface energy into kinetic energy. The latter corresponds to velocity perturbations in the pore-scale flow field behind the invading fluid front, reaching local velocities more than 40 times faster than the constant pump rate. The characteristic length scale of these perturbations exceeds the characteristic pore size by more than an order of magnitude. These flow field observations suggest that nonlocal dynamic effects may be long-ranged even at low capillary numbers, impacting the local viscous-capillary force balance and the representative elementary volume. Furthermore, the velocity perturbations can enhance unsaturated dispersive mixing and colloid transport and yet, are not accounted for in current models. Overall, this work shows that 4D X-ray velocimetry opens the way to solve long-standing fundamental questions regarding flow and transport in porous materials, underlying models of, e.g., groundwater pollution remediation and subsurface storage of CO2 and hydrogen.

AB - Many environmental and industrial processes depend on how fluids displace each other in porous materials. However, the flow dynamics that govern this process are still poorly understood, hampered by the lack of methods to measure flows in optically opaque, microscopic geometries. We introduce a 4D microvelocimetry method based on high-resolution X-ray computed tomography with fast imaging rates (up to 4 Hz). We use this to measure flow fields during unsteady-state drainage, injecting a viscous fluid into rock and filter samples. This provides experimental insight into the nonequilibrium energy dynamics of this process. We show that fluid displacements convert surface energy into kinetic energy. The latter corresponds to velocity perturbations in the pore-scale flow field behind the invading fluid front, reaching local velocities more than 40 times faster than the constant pump rate. The characteristic length scale of these perturbations exceeds the characteristic pore size by more than an order of magnitude. These flow field observations suggest that nonlocal dynamic effects may be long-ranged even at low capillary numbers, impacting the local viscous-capillary force balance and the representative elementary volume. Furthermore, the velocity perturbations can enhance unsaturated dispersive mixing and colloid transport and yet, are not accounted for in current models. Overall, this work shows that 4D X-ray velocimetry opens the way to solve long-standing fundamental questions regarding flow and transport in porous materials, underlying models of, e.g., groundwater pollution remediation and subsurface storage of CO2 and hydrogen.

KW - 3D velocimetry

KW - hydrogeology

KW - multiphase flow

KW - porous media

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JO - Proceedings of the National Academy of Sciences of the United States of America

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ER -

4D microvelocimetry reveals multiphase flow field perturbations in porous media

Abstract

Bibliographical note

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Keywords

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