Tuning flow asymmetry with bio-inspired soft leaflets

TL;DR

This study investigates how bio-inspired asymmetric soft leaflets in microfluidic channels can passively control flow direction and resistance, combining experiments, simulations, and theory to optimize flow asymmetry.

Contribution

It introduces a novel design of asymmetric soft leaflets inspired by biological systems to passively tune flow properties in microchannels, supported by combined experimental and theoretical analysis.

Findings

Flow asymmetry can be maximized by tuning leaflet geometry.

Soft leaflets effectively control flow resistance and direction.

The approach aids in understanding biological flow mechanisms and designing microfluidic devices.

Abstract

In Nature, liquids often circulate in channels textured with leaflets, cilia or porous walls that deform with the flow. These soft structures are optimized to passively control flows and inspire the design of novel microfluidic and soft robotic devices. Yet so far the relationship between the geometry of the soft structures and the properties of the flow remains poorly understood. Here, taking inspiration from the lymphatic system, we devise millimetric scale fluidic channels with asymmetric soft leaflets that passively increase (reduce) the channel resistance for forward (backward) flows. Combining experiments, numerics and analytical theory, we show that tuning the geometry of the leaflets controls the flow properties of the channel through an interplay between asymmetry and nonlinearity. In particular, we find the conditions for which flow asymmetry is maximal. Our results open the way to a better characterization of biological leaflet malformations and to more accurate control of flow orientation and pumping mechanisms for microfluidics and soft robotic systems.