Argon: Difference between revisions

Argon has a mass of 39.948 umas. Sadus and Prausnitz have shown that three-body repulsion makes a significant contribution to three-body interactions in the liquid phase (Ref. 5) (for use of the Axilrod-Teller interaction see Refs. 6 and 7). However, the Lennard-Jones model has been frequently used due to its simplicity.

Lennard-Jones parameters

The Lennard-Jones parameters for liquid argon are listed in the following table:

Authors	${\displaystyle \epsilon /k_{B}}$ (K)	${\displaystyle \sigma }$ (nm)	Reference
Rowley, Nicholson and Parsonage	119.8	0.3405	Ref. 8
Barker, Fisher and Watts	142.095	0.33605	Ref. 9
White	125.7	0.3345	Ref. 10 parameter set #4

Radial distribution function

Radial distribution function

1. J. L. Yarnell, M. J. Katz, R. G. Wenzel and S. H. Koenig "Structure Factor and Radial Distribution Function for Liquid Argon at 85°K", Physical Review A 7 pp. 2130-2144 (1973)

References

1. H. C. Longuet-Higgins and B. Widom "A rigid sphere model for the melting of argon", Molecular Physics 8 pp. 549-556 (1964)
2. D. Henderson and J. A. Barker "On the solidification of argon", Molecular Physics 14 pp. 587-589 (1968)
3. J. A. Barker, R. A. Fisher and R. O. Watts "Liquid argon: Monte Carlo and molecular dynamics calculations", Molecular Physics 21 pp. 657-673 (1971)
4. F. Lado "Numerical Calculation of the Density Autocorrelation Function for Liquid Argon", Physical Review A 5 pp. 2238-2244 (1972)
5. Richard J. Sadus and J. M. Prausnitz "Three-body interactions in fluids from molecular simulation: Vapor–liquid phase coexistence of argon", Journal of Chemical Physics 104 pp. 4784-4787 (1996)
6. Phil Attard "Pair-hypernetted-chain closure for three-body potentials: Results for argon with the Axilrod-Teller triple-dipole potential", Physical Review A 45 pp. 3659-3669 (1992)
7. J. A. Anta, E. Lomba and M. Lombardero "Influence of three-body forces on the gas-liquid coexistence of simple fluids: The phase equilibrium of argon", Physical Review E 55 pp. 2707-2712 (1997)
8. L. A. Rowley, D. Nicholson and N. G. Parsonage "Monte Carlo grand canonical ensemble calculation in a gas-liquid transition region for 12-6 Argon", Journal of Computational Physics 17 pp. 401-414 (1975)
9. J. A. Barker, R. A. Fisher and R. O. Watts "Liquid argon: Monte carlo and molecular dynamics calculations", Molecular Physics 21 pp. 657-673 (1971)
10. John A. White "Lennard-Jones as a model for argon and test of extended renormalization group calculations", Journal of Chemical Physics 111 pp. 9352-9356 (1999)

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