Asymmetric bistability of chiral particle orientation in viscous shear flows

TL;DR

This study investigates how chiral particles with a spherical head and helical tails reorient in viscous shear flows, revealing asymmetric bistability in their orientation, which advances understanding of bacterial rheotaxis and chiral particle transport.

Contribution

The paper introduces a controlled microfabrication method and experimental model to analyze chiral particle orientation dynamics, demonstrating asymmetric bistability and providing a quantitative theoretical explanation.

Findings

Demonstrated asymmetric bistability in particle orientation.

Quantitative agreement between experiments and boundary element simulations.

Insights into chiral particle transport and bacterial rheotaxis.

Abstract

The migration of helical particles in viscous shear flows plays a crucial role in chiral particle sorting. Attaching a non-chiral head to a helical particle leads to a rheotactic torque inducing particle reorientation. This phenomenon is responsible for bacterial rheotaxis observed for flagellated bacteria as Escherichia coli in shear flows. Here we use a high-resolution microprinting technique to fabricate micro-particles with controlled and tunable chiral shape consisting of a spherical head and helical tails of various pitch and handedness. By observing the fully time-resolved dynamics of these micro-particles in microfluidic channel flow, we gain valuable insights into chirality-induced orientation dynamics. Our experimental model system allows us to examine the effects of particle elongation, chirality, and head-heaviness for different flow rates on the orientation dynamics, while minimizing the influence of Brownian noise. Through our model experiments we demonstrate the existence of asymmetric bistability of the particle orientation perpendicular to the flow direction. We quantitatively explain the particle equilibrium orientations as a function of particle properties, initial conditions and flow rates, as well as the time-dependence of the reorientation dynamics through a theoretical model. The model parameters are determined using boundary element simulations and excellent agreement with experiments is obtained without any adjustable parameters. Our findings lead to a better understanding of chiral particle transport, bacterial rheotaxis and might allow the development of targeted delivery applications.