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Dynamic Fluid Connectivity Controls Solute Dispersion in Multiphase Porous Media Flow

Joachim Mathiesen, Gaute Linga, Marek Krzysztof Misztal, François Renard, Tanguy Le Borgne

2023Geophysical Research Letters21 citationsDOIOpen Access PDF

Abstract

Abstract Solute transport in multiphase flow through porous media plays a central role in many natural systems and geoengineering applications. The interplay between fluid flow and capillary forces leads to transient flow dynamics and phase distributions. However, it is not known how such dynamic flow affects the dispersion of transported species. Here, we use highly resolved numerical simulations of immiscible two‐phase flow to investigate dispersion in multiphase flows. We show that repeated activation and deactivation of different flow pathways under the effect of capillary forces accelerates the spreading of solutes compared to single phase flow. We establish the transport laws under dynamic multiphase flows by linking the dispersion coefficient to the Bond number, the ratio of the force driving the flow and the surface tension. Our results determine the controlling factors for solute dispersion in porous media, opening a range of applications for understanding and controlling transport in porous geological systems.

Topics & Concepts

Porous mediumMultiphase flowDispersion (optics)MechanicsFlow (mathematics)Capillary actionMaterials scienceFluid dynamicsSurface tensionCapillary numberTaylor dispersionPhase (matter)PorosityThermodynamicsChemistryPhysicsDiffusionOpticsComposite materialOrganic chemistryGroundwater flow and contamination studiesCO2 Sequestration and Geologic InteractionsEnhanced Oil Recovery Techniques
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