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The temperature dependence of the helical pitch in a cholesteric liquid crystal

Robert A. Skutnik, Jan-Christoph Eichler, Marco G. Mazza, Martin Schoen

2021Molecular Physics15 citationsDOIOpen Access PDF

Abstract

We investigate the temperature dependence of the helical pitch of a cholesteric liquid crystal by means of Monte Carlo simulations. We carry out both lattice and off-lattice simulations to assess the impact of geometric and modelling constraints on the properties of the cholesteric phase. For the off-lattice simulations we develop boundary conditions commensurate with the cholesteric phase and derive an analytic expression for the helical wavenumber q that works well qualitatively. We find that the common simplification of constraining the orientation of the mesogens to planes normal to the helical axis makes q temperature-independent, as predicted by a mean-field theory of van der Meer et al. [J. Chem. Phys. 65, 3935 (1976)]. However, if mesogens are allowed to rotate in three dimensions, q will increase with temperature, as the isotropic-cholesteric transition is approached from below, in agreement with experiments for a number of substances. Our simulations indicate that the temperature-independent q is merely a consequence of the overly restricted orientational degrees of freedom to points on the unit circle in the model on which the mean-field theory is based.

Topics & Concepts

IsotropyLiquid crystalLattice (music)Monte Carlo methodCholesteric liquid crystalDegrees of freedom (physics and chemistry)Periodic boundary conditionsWavenumberCondensed matter physicsPhase (matter)Boundary value problemPhysicsStatistical physicsThermodynamicsMaterials scienceOpticsMathematicsQuantum mechanicsStatisticsAcousticsLiquid Crystal Research AdvancementsTheoretical and Computational PhysicsSpectroscopy and Quantum Chemical Studies