Light-Activated Motion, Geometry- and Confinement-Induced Optical Effects of 2D Platelets in a Nematic Liquid Crystal

TL;DR

This study explores how light-activated micron-sized platelets in nematic liquid crystals can self-propel and induce phase transitions, revealing regimes influenced by temperature, light, and confinement, with implications for tunable photonic systems.

Contribution

It introduces a novel quasi-2D active system where light induces motion and phase changes in colloids within nematic liquid crystals, supported by continuum-theory simulations.

Findings

Identification of three distinct regimes based on temperature, light, and confinement.

Prediction of stationary states in 3D confinement through simulations.

Demonstration of light-induced self-propulsion and phase transition behaviors.

Abstract

Motile liquid crystal (LC) colloids show peculiar behavior due to the high sensitivity to external stimuli driven by the LC elastic and surface effects. However, few studies focus on harnessing the LC phase transitions to propel colloidal inclusions by the nematic-isotropic (NI) interface. We engineer a quasi-2D active system consisting of solid micron-sized light-absorbent platelets immersed in a thermotropic nematic LC. The platelets self-propel in the presence of light while self-inducing a localized NI phase transition. The sample's temperature, light intensity, and confinement determine three different regimes: a 2D large regime where the platelet-isotropic phase bubble is static and the NI interface remains stable; a compact motile-2D regime where the NI interface lies closer to the platelet's contour; and a motile-3D-confinement regime characterized by the emergence of multipolar configurations of the LC. We perform continuum-theory simulations that predict stationary platelet-LC states when confined in 3D. Our study in an intrinsically far-from-equilibrium landscape is crucial for designing simple synthetic systems that contribute to our understanding of harnessing liquid crystals' phase transitions to propel colloidal inclusions and trigger tunable topological reconfigurations leading to photonic responses.