Phase behavior of two-dimensional hard rod fluids
Publication date
2000
Authors
Bates, M.A.
Frenkel, D.
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DOI
Document Type
Article
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Abstract
Monte Carlo simulations are used to study two-dimensional hard rod fluids consisting of
spherocylinders confined to lie in a plane. The phase behavior is mapped out as a function of the
aspect ratio (L/D) of the particles, from the hard disc limit at one extreme (L/D50) to the thin
hard needle limit at the other (L/D5`). For long rods, a 2D nematic phase is observed at high
density in which the orientational correlation functions decay algebraically, indicating that the phase
does not possess true long range orientational order. The simulation data indicate that the transition
from this phase to the low density isotropic phase is continuous, via a Kosterlitz–Thouless
disclination unbinding type mechanism, rather than first order. For short rods the nematic phase
disappears so that, on expansion, the solid phase undergoes a first order transition directly to an
isotropic phase. Although the latter phase is globally isotropic, we find evidence for strong local
positional and orientational correlations between the particles. Where possible, the simulation
results are compared and contrasted to experimental, simulation and theoretical data for other
two-dimensional liquid crystalline systems.