Bubble damping of non-stationary oscillatory flow stabilization in microfluidic systems

TL;DR

This paper develops a theoretical model explaining how trapped air passively dampens oscillatory flows in microfluidics, validated by experiments, enabling better control of flow stability in microfluidic applications.

Contribution

A first-principles model describing the effects of trapped air on oscillatory microfluidic flow, unifying air compressibility and fluidic resistance into a predictive framework.

Findings

Model accurately predicts amplitude reduction and phase shift.

Experimental validation across various conditions.

Transforms trapped air into a predictable flow control element.

Abstract

The inherent instability of oscillatory flows presents a significant challenge in microfluidics, impairing performance in different applications from particle detachemnt to organs-on-a-chip. Trapped air inside a microfluidic system passively dampens these fluctuations because of the compressible nature of air. However, a foundational theoretical model that describes this effect has remained elusive. Here, a first-principles model that fully characterizes the effects of a trapped air volume in oscillatory microfluidic flow is derived. The model identifies a dimensionless product as the governing parameter, unifying the interplay between air compressibility and fluidic resistance. It precisely predicts the volume displacement dynamics of the liquid front, which compared with the original flow, it presents amplitude reduction, phase shift, and transient drift. The theoretical framework was validated with different experiments across a broad range of conditions. This work transforms trapped air from a source of unpredictability into a powerful, predictable element for tailoring oscillatory flow stability, providing a rigorous design tool for microfluidic systems.