Diffusioosmotic flow in a soft microfluidic configuration induces fluid-structure instability

TL;DR

This paper investigates how diffusioosmotic flow in soft microfluidic channels causes fluid-structure instability, leading to elastic deformation and collapse, through a reduced-order model, stability analysis, and finite-element validation.

Contribution

It introduces a reduced-order model and stability analysis to understand diffusioosmotic flow-induced instabilities in soft microfluidic channels, validated by simulations.

Findings

Above a concentration gradient threshold, negative pressures induce instability.

Fluid-structure instability causes the elastic top to collapse onto the bottom.

Three dynamic regimes identified through stability analysis.

Abstract

Diffusioosmotic flow arises in microfluidic configurations due to solute concentration gradients. In soft microfluidic channels, internal pressure gradients generated by diffusioosmotic flow to conserve mass result in elastic deformation of the channel walls, triggering fluid-structure interaction. In this work, we analyze the fluid-structure interaction between diffusioosmotic flow of an electrolyte solution and a deformable microfluidic channel. We provide insight into the physical behavior of the system by developing a reduced-order model, in which a viscous film is confined between a rigid bottom surface and an elastic top substrate, represented as a rigid plate connected to a linear spring. Considering a slender configuration and applying the lubrication approximation, we derive a set of two-way coupled governing equations describing the evolution of the fluidic film thickness and the solute concentration. Our theoretical predictions show that above a certain concentration gradient threshold, negative pressures induced by diffusioosmotic flow give rise to fluid-structure instability, causing the elastic top substrate to collapse onto the bottom surface. We employ theoretical analysis to elucidate the underlying physical mechanisms for the onset of fluid-structure instability by performing a linear stability analysis of the system and identifying three distinct dynamic regimes. We validate our theoretical results with finite-element simulations and find excellent agreement. The understanding of this instability is of fundamental importance for improving the control and design of microfluidic systems driven by diffusioosmotic flow and containing soft elements.