Computer simulation study of the global phase behavior of linear rigid Lennard-Jones chain molecules : comparison with flexible models
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Abstract
The global phase behavior ~i.e., vapor-liquid and fluid-solid equilibria! of rigid linear Lennard-Jones
~LJ! chain molecules is studied. The phase diagrams for three-center and five-center rigid model
molecules are obtained by computer simulation. The segment-segment bond lengths are L5s, so
that models of tangent monomers are considered in this study. The vapor-liquid equilibrium
conditions are obtained using the Gibbs ensemble Monte Carlo method and by performing
isobaric-isothermal NPT calculations at zero pressure. The phase envelopes and critical conditions
are compared with those of flexible LJ molecules of tangent segments. An increase in the critical
temperature of linear rigid chains with respect to their flexible counterparts is observed. In the limit
of infinitely long chains the critical temperature of linear rigid LJ chains of tangent segments seems
to be higher than that of flexible LJ chains. The solid-fluid equilibrium is obtained by Gibbs–Duhem
integration, and by performing NPT simulations at zero pressure. A stabilization of the solid phase,
an increase in the triple-point temperature, and a widening of the transition region are observed for
linear rigid chains when compared to flexible chains with the same number of segments. The
triple-point temperature of linear rigid LJ chains increases dramatically with chain length. The
results of this work suggest that the fluid-vapor transition could be metastable with respect to the
fluid-solid transition for chains with more than six LJ monomer units.
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Bibliographic citation
Galindo, A., Vega, C., Sanz, E., MacDowell, LG., Miguel Agustino, E., Jiménez Blas, F.: "Computer simulation study of the global phase behavior of linear rigid Lennard-Jones chain molecules : comparison with flexible models". Journal of Chemical Physics. Vol. 120, n. 8, págs. 3957-3967, (2004). ISSN 0021-9606














