What question did this study set out to answer?

This research aims to explore the impact of phase topology on hysteresis during fluid injection and withdrawal in porous media.

February 12, 2026

Topological evolution: An unexplored aspect of hysteresis for multiphase flow in porous media

Key Points

This research aims to explore the impact of phase topology on hysteresis during fluid injection and withdrawal in porous media.
Conducted experiments to observe fluid behavior in porous media.
Developed a generalized model to analyze capillary pressure and interfacial area.
Utilized a piecewise non-linear model to predict topological evolution.
Identified distinct topological evolution for the nonwetting fluid compared to capillary pressure and interfacial area.
Demonstrated that saturation paths with the same capillary pressure yield different topologies.
Reveal predictable trajectories for nonwetting phase topological evolution.

Abstract

The role of phase topology in hysteresis during fluid injection and withdrawal in porous media is not fully understood. We address this by providing experimental and theoretical evidence on three key findings. (1) The topological evolution of the nonwetting fluid is distinct from the capillary pressure and the specific interfacial area, as shown by experiments and a generalized model. (2) Saturation paths with identical capillary pressure and interfacial area show different topologies, revealing insights into energy dissipation and phase connectivity. (3) The topological evolution of the nonwetting phase follows predictable trajectories captured by a piecewise non-linear model. These findings offer practical implications for optimizing subsurface hydrogen and carbon dioxide storage systems and provide a novel approach to study complex systems with topological singularities.

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Topological evolution: An unexplored aspect of hysteresis for multiphase flow in porous media

Key Points

Abstract

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