On the Viscous Crossflow During the Foam Displacement in Two-Layered Porous Media

Foam flow in porous media increased the scientific community’s attention due to several potential industrial applications, including remediation of contaminated aquifers, soil remediation, acid diversion, and hydrocarbon recovery. Natural reservoirs typically have fractured and multi-layered structu...

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Veröffentlicht in:	Transport in porous media 2024-12, Vol.151 (15), p.2835-2857
Hauptverfasser:	Vásquez, A. J. Castrillón, Paz, P. Z. S., Chapiro, G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aquifers Civil Engineering Classical and Continuum Physics Cross flow Direct numerical simulation Earth and Environmental Science Earth Sciences Equilibrium Fluid flow Geotechnical Engineering & Applied Earth Sciences Hydrocarbons Hydrogeology Hydrology/Water Resources Incompressible flow Industrial applications Industrial Chemistry/Chemical Engineering Multilayers Oil recovery Permeability Porosity Porous media Simulation Soil layers Soil permeability Soil porosity Soil remediation Surfactants Traveling waves Two phase flow Water
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container_title	Transport in porous media
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creator	Vásquez, A. J. Castrillón Paz, P. Z. S. Chapiro, G.
description	Foam flow in porous media increased the scientific community’s attention due to several potential industrial applications, including remediation of contaminated aquifers, soil remediation, acid diversion, and hydrocarbon recovery. Natural reservoirs typically have fractured and multi-layered structures. We investigate an immiscible incompressible two-phase foam flow in an internally homogeneous two-layered porous medium with different porosities and absolute permeabilities. For our analysis, we extended the previous result, evidencing that the presence of foam induces the existence of a single flow front in both layers. Using the traveling wave solution, we classify the foam flow depending on the absolute permeability and the porosity ratio between layers. We show that the mass crossflow between layers is connected to the relative position of the flow front in these layers and that the porosity difference between layers impacts the mass crossflow. All analytical estimates were supported by direct numerical simulations.
doi_str_mv	10.1007/s11242-024-02135-3
format	Article
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subjects	Aquifers Civil Engineering Classical and Continuum Physics Cross flow Direct numerical simulation Earth and Environmental Science Earth Sciences Equilibrium Fluid flow Geotechnical Engineering & Applied Earth Sciences Hydrocarbons Hydrogeology Hydrology/Water Resources Incompressible flow Industrial applications Industrial Chemistry/Chemical Engineering Multilayers Oil recovery Permeability Porosity Porous media Simulation Soil layers Soil permeability Soil porosity Soil remediation Surfactants Traveling waves Two phase flow Water
title	On the Viscous Crossflow During the Foam Displacement in Two-Layered Porous Media
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