Finite-size effects at first-order isotropic-to-nematic transitions

Abstract

We present simulation data of first-order isotropic-to-nematic transitions in lattice models of liquid crystals and locate the thermodynamic limit inverse transition temperature ε∞ via finite-size scaling. We observe that the inverse temperature of the specific heat maximum can be consistently extrapolated to ε∞ assuming the usual α / Ld dependence, with L the system size, d the lattice dimension and proportionality constant α. We also investigate the quantity εL,k, the finite-size inverse temperature where k is the ratio of weights of the isotropic to nematic phase. For an optimal value k = k opt, εL,k versus L converges to ε∞ much faster than α/Ld, providing an economic alternative to locate the transition. Moreover, we find that α k opt / L∞, with L∞ the latent heat density. This suggests that liquid crystals at first-order IN transitions scale approximately as q-state Potts models with q k opt.