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Self-Consistent Theory of Second-Order Elastic Constants with an Application to Noble-Gas Crystals

Michael L. KleinDivision of Chemistry, National Research Council, Ottawa 2, CanadaG. K. HortonDivision of Chemistry, National Research Council, Ottawa 2, CanadaVictor GoldmanDivision of Chemistry, National Research Council, Ottawa 2, Canada
1970en
ABI

Abstract

Formal expressions for the first two strain derivatives of the first-order self-consistent free-energy density are rederived, and presented in a form suitable for numerical computation. The first strain derivative is the first-order self-consistent stress tensor and the second derivatives are the corresponding elastic constants. Because of the self-consistency condition, these elastic constants contain thermally averaged third-and fourth-order force constants. Special reference is made to an approximation first introduced by Horner in 1967. The expressions are applied to solid Ne, Ar, Kr, and Xe using a (12-6) Mie-Lennard-Jones potential. Calculations are carried out for the temperature range 0\ifmmode^\circ\else\textdegree\fi{}K to their respective melting points at zero pressure. The calculations are presented for the 0\ifmmode^\circ\else\textdegree\fi{}K volume, the experimental volume at zero pressure, and the volume produced by first-order self-consistent theory (SC). The volume effect is often large. However, at the same volume, the bulk moduli derived from ${F}_{\mathrm{ISC}}$ and ${F}_{\mathrm{SC}}$ differ by at most a few percent. This is taken to indicate the probable accuracy of our results.

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