Chirality Amplification and Deracemization in Liquid Crystals
Abstract
Liquid crystal mesophases of achiral molecules are normally achiral, yet in a few materials they spontaneously deracemize and form right- and left-handed chiral domains. One mechanism that drives deracemization is molecular shape fluctuations between axial chiral conformations, where molecular interactions favor matching chirality and promote helical twist. Cooperative chiral ordering may also play a role in chirality amplification, as when a tiny fraction of chiral dopant drives a nematic phase to become cholesteric. We present a model of cooperative chiral ordering in liquid crystals using Maier-Saupe theory, and predict a phase diagram with a deracemized cholesteric phase as well as racemic nematic and isotropic phases. Our model also predicts chirality amplification in the nematic phase, which may be observed even in materials where the deracemization transition is preempted by a transition to another phase. We compare these results with Monte Carlo simulation studies of the switchable chiral Lebwohl-Lasher model, where each spin switches between right- and left-handed chiral states. Simulation results validate the predicted phase diagram, demonstrate chiral amplification in the racemic nematic phase, and reveal coarsening dynamics in the deracemized phase. Our results suggest that cooperative chiral ordering via molecular shape transitions is a common mechanism in liquid crystals.