Computer simulation of charged hard spherocylinders at low temperatures

In this work we report the stability of liquid crystalline phases of charged hard spherocylinders (CHSC) of aspect ratio L/σ=5 at low temperatures using NPT Monte Carlo computer simulations. Following the methodology used in previous work [C. Avendaño, A. Gil-Villegas, E. González-Tovar, J. Chem. Phys. 128, 044506 (2008); Chem. Phys. Lett. 470, 67 (2009)], long-range coulombic interactions are handled using the Wolf method. The supramolecular organization of CHSC is obtained by compression of a low-density isotropic state. The system under consideration exhibits the expected isotropic, nematic, smectic-A, and crystal phases. However two important phenomena emerge at low temperatures, namely the existence of an isotropic-nematic-smectic triple point, with the ending of the nematic phase for lower temperatures, and the apparent hexatic arrangement of the layers in the smectic phases. Assuming that the smectic-layers behave as quasi-bidimensional systems, lowering the temperatures is possible to observe the formation of hexatic phases, which are detected analysing the structure factor, order parameters and distribution functions. This hexatic ordering indicates that the CHSC phase diagram presents a smectic-B phase at low temperatures. © 2011 Taylor %26 Francis.

computer simulation; liquid crystals; Monte Carlo method B phase; Bidimensional system; Coulombic interactions; Crystal phasis; Hexatic phasis; Isotropic state; Liquid-crystalline phasis; Low temperatures; MONTE CARLO; Nematic phase; Order parameter; Smectic phasis; Smectic-A; Spherocylinders; Structure factors; Supramolecular organizations; Triple points; Aspect ratio; Computational methods; Crystals; Distribution functions; Liquid crystals; Monte Carlo methods; Phase diagrams; Computer simulation

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