Thermodynamic properties of the 3D Lennard-Jones/spline model
Journal article, Peer reviewed
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Date
2019Metadata
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- Publikasjoner fra CRIStin - SINTEF Energi [1721]
- SINTEF Energi [1857]
Abstract
In the Lennard-Jones spline (LJ/s) model, the Lennard-Jones (LJ) potential is truncated and
splined so that both the pair potential and the force continuously approach zero at rc 1:74 .
It exhibits the same structural features as the LJ model, but the thermodynamic properties
are di erent due to the shorter range of the potential. One advantage of the model is that
simulation times are much shorter. In this work, we present a systematic map of the thermo-
dynamic properties of the LJ/s model from molecular dynamics and Gibbs ensemble Monte
Carlo simulations. Accurate results are presented for gas/liquid, liquid/solid and gas/solid co-
existence curves, supercritical isotherms up to a reduced temperature of 2 (in LJ units), surface
tensions, speed of sound, the Joule-Thomson inversion curve, and the second to fourth virial
coe cients. The critical point for the LJ/s model is estimated to be T
c = 0:885 0:002 and
P
c = 0:075 0:001, respectively. The triple point is estimated to T
tp = 0:547 0:005 and
P
tp = 0:0016 0:0002. Despite the simplicity of the model, the acentric factor was found to be
as large as 0:07 0:02. The coexistence densities, saturation pressure, and supercritical isotherms
of the LJ/s model were fairly well represented by the Peng-Robison equation of state. We nd
that Barker-Henderson perturbation theory works much more poorly for the LJ/s model than
for the LJ model. The rst-order perturbation theory overestimates the critical temperature and
pressure by about 10% and 90%, respectively. A second-order perturbation theory that uses the
mean compressibility approximation shifts the critical point closer to simulation data, but makes
the prediction of the saturation densities worse. It is hypothesized that the reason for this is
that the mean compressibility approximation gives a poor representation of the second-order
perturbation term for the LJ/s model and that a correction factor is needed at high densities.
Our main conclusion is that we at the moment do not have a theory or model that adequately
represents the thermodynamic properties of the LJ/s system.