Lennard-Jones equation of state: Difference between revisions

The equation of state (EOS) of the Lennard-Jones model. Lennard-Jones EOS are widely used – especially in soft matter physics. Lennard-Jones EOS are also often used as a point of departure for the development of models of complex fluids. A large number of Lennard-Jones EOS have been developed in the past. Several popular Lennard-Jones EOS for the fluid phases were systematically compared and evaluated to simulation data ^[1][2]. The one of Kolafa and Nezbeda was therein found to be the most robust and accurate Lennard-Jones EOS. Ref. ^[1] gives a comprehensive review of EOS of the Lennard-Jones fluid. Overall, it was found that none of the presently available EOS gives a satisfactory description of the Lennard-Jones fluid, which makes the development of LJ EOS still an active field.

Johnson, Zollweg and Gubbins[edit]

Johnson, Zollweg and Gubbins ^[3] proposed an equation of state based on 33 parameters within a modified Benedict, Webb and Rubin equation of state, which accurately reproduces the vapour-liquid equilibrium curve.

Kolafa and Nezbeda[edit]

The Kolafa and Nezbeda equation of state ^[4] provides us with the Helmholtz energy function: (Eq. 30):

${\displaystyle A=A_{\mathrm {HS} }+\exp(-\gamma \rho ^{2})\rho T\Delta B_{2,{\mathrm {hBH} }}+\sum _{ij}C_{ij}T^{i/2}\rho ^{j}}$

the compressibility factor (Eq. 31)

${\displaystyle z\equiv {\frac {P}{\rho T}}=z_{\mathrm {HS} }+\rho (1-2\gamma \rho ^{2})\exp(-\gamma \rho ^{2})\Delta B_{2,{\mathrm {hBH} }}+\sum _{ij}jC_{ij}T^{i/2-1}\rho ^{j}}$

and the internal energy (Eq. 32)

${\displaystyle U={3(z_{\rm {HS}}-1) \over d_{\rm {hBH}}}\,{\partial d_{\rm {hBH}} \over \partial (1/T)}+\rho \exp(-\gamma \rho ^{2})\,{\partial \Delta B_{\rm {2,hBH}} \over \partial (1/T)}-\sum _{ij}\left({i \over 2}-1\right)C_{ij}\,T^{i/2}\rho ^{j}}$

On the following page is the FORTRAN code for the Kolafa and Nezbeda equation of state.

Ree[edit]

The Ree equation of state ^[5] is an extension of the earlier work of Hansen ^[6] in the high temperature region.

Boltachev and Baidakov[edit]

Boltachev and Baidakov have paid particular attention to including data from the metastable region ^[7].

Pieprzyk-Brańka-Maćkowiak and Heyes[edit]

The Pieprzyk-Brańka-Maćkowiak and Heyes equation of state ^[8] consists of a parameterisation of the modified Benedict, Webb and Rubin equation of state.

PeTS[edit]

The PeTS (perturbed truncated and shifted) equation of state for pure components ^[9] and mixtures ^[10] (only for the Lennard-Jones truncated and shifted fluid).

References[edit]

Related reading

• J. J. Nicolas, K. E. Gubbins, W. B. Streett and D. J. Tildesley "Equation of state for the Lennard-Jones fluid", Molecular Physics 37 pp. 1429-1454 (1979)
• Karel Aim, Jirí Kolafa, Ivo Nezbeda and Horst L. Vörtler "The Lennard-Jones fluid revisited: new thermodynamic data and new equation of state", Fluid Phase Equilibria 83 pp. 15-22 (1993)
• Hertanto Adidharma and Maciej Radosz "The LJ-Solid Equation of State Extended to Thermal Properties, Chain Molecules, and Mixtures", Industrial and Engineering Chemistry Research 43 pp. 6890 - 6897 (2004)
• David M. Eike, Joan F. Brennecke, and Edward J. Maginn "Toward a robust and general molecular simulation method for computing solid-liquid coexistence", Journal of Chemical Physics 122 014115 (2005)
• Sergey A. Khrapak and Gregor E. Morfill "Accurate freezing and melting equations for the Lennard-Jones system", Journal of Chemical Physics 134 094108 (2011)
• Monika Thol, Gabor Rutkai, Andreas Köster, Rolf Lustig, Roland Span, and Jadran Vrabec "Equation of State for the Lennard-Jones Fluid", Journal of Physical and Chemical Reference Data 45 023101 (2016)

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