On the boundary layer structure near a highly permeable porous interface

TL;DR

This paper uses matched asymptotic expansions to analyze the boundary layer structure near a highly permeable porous interface in laminar flow, revealing detailed flow transitions and stresses relevant to bioengineering and erosion.

Contribution

It provides a novel analytical framework for understanding flow transitions and stresses at permeable interfaces, including high-Reynolds-number boundary layer structures and coupling conditions in 3D unsteady flows.

Findings

Flow transitions from Poiseuille to plug flow analyzed.

Coupling conditions for high-Reynolds-number flow derived.

Internal and interfacial stresses quantified for bioengineering applications.

Abstract

The method of matched asymptotic expansions is used to study the canonical problem of steady laminar flow through a narrow two-dimensional channel blocked by a tight-fitting finite-length highly permeable porous obstacle. We investigate the behaviour of the local flow close to the interface between the single-phase and porous regions (governed by the incompressible Navier--Stokes and Darcy flow equations, respectively). We solve for the flow in these inner regions in the limits of low and high Reynolds number, facilitating an understanding of the nature of the transition from Poiseuille to plug to Poiseuille flow in each of these limits. Significant analytic progress is made in the high-Reynolds-number limit, and we explore in detail the rich boundary layer structure that occurs. We consider the three-dimensional generalization to unsteady laminar flow through and around a tight-fitting highly permeable cylindrical porous obstacle within a Hele-Shaw cell. For the high-Reynolds-number limit, we give the coupling conditions and interfacial stress in terms of the outer flow variables, allowing information from a nonlinear three-dimensional problem to be obtained by solving a linear two-dimensional problem. Finally, we illustrate the utility of our analysis by considering the specific example of time-dependent forced far-field flow in a Hele-Shaw cell containing a porous cylinder with a circular cross-section. We determine the internal stress within the porous obstacle, which is key for tissue engineering applications, and the interfacial stress on the boundary of the porous obstacle, which has applications to biofilm erosion. In the high-Reynolds-number limit, we demonstrate that the fluid inertia can result in the cylinder experiencing a time-independent net force, even when the far-field forcing is periodic with zero mean.