Kalde, Anna ; Lippold, Sophia ; Loelsberg, Jonas ; Mertens, Ann-Kathrin ; Linkhorst, John ; Tsai, Peichun Amy ; Wessling, Matthias (2022)
Surface Charge Affecting Fluid–Fluid Displacement at Pore Scale.
In: Advanced Materials Interfaces, 9 (9)
doi: 10.1002/admi.202101895
Article, Bibliographie
Abstract
Efficiency in fluid– fluid displacement is drastically reduced by viscous fingering, limiting the overall effectiveness in enhanced oil recovery, membrane science, and lateral flow devices used in biomedical applications. Local instabilities at the fluid– fluid interface lead to finger-like patterns when a less viscous fluid displaces an immiscible fluid of higher viscosity. This widely observed phenomenon in multiphase flow inside porous media is infamously intricate to control, especially for given geometry and viscosity ratio. The presented study uses a highly controlled microfluidic porous network structure with tailored ionic surface strength. The direct correlation of viscous fingering evolution on the porous structure's zeta potential at a pore-scale level is demonstrated via polyelectrolyte coatings using a layer-by-layer technique. Displacement patterns are tuned from vigorous viscous fingering over stable displacement to corner flow events across a broad range of capillary numbers depending on the applied coatings. The experimental data show an increasing trend of oil recovery with increasing surface wettability, consistent with several previous findings. Furthermore, the results reveal that surface zeta potential correlates positively with recovery rate but negatively with the displacement stability quantified by the fractal dimension. These insights enable a more targeted porous media design to obtain optimal multiphase flow control.
Item Type: | Article |
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Erschienen: | 2022 |
Creators: | Kalde, Anna ; Lippold, Sophia ; Loelsberg, Jonas ; Mertens, Ann-Kathrin ; Linkhorst, John ; Tsai, Peichun Amy ; Wessling, Matthias |
Type of entry: | Bibliographie |
Title: | Surface Charge Affecting Fluid–Fluid Displacement at Pore Scale |
Language: | English |
Date: | February 2022 |
Journal or Publication Title: | Advanced Materials Interfaces |
Volume of the journal: | 9 |
Issue Number: | 9 |
DOI: | 10.1002/admi.202101895 |
Abstract: | Efficiency in fluid– fluid displacement is drastically reduced by viscous fingering, limiting the overall effectiveness in enhanced oil recovery, membrane science, and lateral flow devices used in biomedical applications. Local instabilities at the fluid– fluid interface lead to finger-like patterns when a less viscous fluid displaces an immiscible fluid of higher viscosity. This widely observed phenomenon in multiphase flow inside porous media is infamously intricate to control, especially for given geometry and viscosity ratio. The presented study uses a highly controlled microfluidic porous network structure with tailored ionic surface strength. The direct correlation of viscous fingering evolution on the porous structure's zeta potential at a pore-scale level is demonstrated via polyelectrolyte coatings using a layer-by-layer technique. Displacement patterns are tuned from vigorous viscous fingering over stable displacement to corner flow events across a broad range of capillary numbers depending on the applied coatings. The experimental data show an increasing trend of oil recovery with increasing surface wettability, consistent with several previous findings. Furthermore, the results reveal that surface zeta potential correlates positively with recovery rate but negatively with the displacement stability quantified by the fractal dimension. These insights enable a more targeted porous media design to obtain optimal multiphase flow control. |
Uncontrolled Keywords: | fluid patterns, fluid– fluid displacement, microfluidics, porous media, surface charge, viscous fingering |
Divisions: | 16 Department of Mechanical Engineering 16 Department of Mechanical Engineering > Chair for Process Engineering of Electrochemical Systems |
Date Deposited: | 13 Sep 2023 11:13 |
Last Modified: | 13 Sep 2023 11:13 |
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