Anharmonic free energy of lattice vibrations in fcc crystals from a mean-field bond

Thomas D. Swinburne; Jan Janssen; Mira Todorova; Gideon Simpson; Petr Plechac; Mitchell Luskin; Jörg Neugebauer

doi:10.1103/PhysRevB.102.100101

Anharmonic free energy of lattice vibrations in fcc crystals from a mean-field bond

Thomas D. Swinburne, Jan Janssen, Mira Todorova, Gideon Simpson, Petr Plechac, Mitchell Luskin, Jörg Neugebauer

Mathematics

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6 Scopus citations

Abstract

It has recently been shown that the ab initio anharmonic free energy of fcc crystals can be approximated to meV/atom accuracy by a lattice of anharmonic nearest-neighbor bonds, where the bonding potential can be efficiently parametrized from the target system. We develop a mean-field approach for the free energy of a general bond lattice, analytically accounting for strong bond-bond correlations while enforcing material compatibility and thermodynamic self-consistency. Applying our fundamentally anharmonic model to fcc crystals yields free energies within meV/atom of brute force thermodynamic integration for core seconds of computational effort. Potential applications of this approach in computational materials science are discussed.

Original language	English (US)
Article number	100101
Journal	Physical Review B
Volume	102
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevB.102.100101
State	Published - Sep 2020

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© 2020 American Physical Society.

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AU - Swinburne, Thomas D.

AU - Janssen, Jan

AU - Todorova, Mira

AU - Simpson, Gideon

AU - Plechac, Petr

AU - Luskin, Mitchell

AU - Neugebauer, Jörg

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AB - It has recently been shown that the ab initio anharmonic free energy of fcc crystals can be approximated to meV/atom accuracy by a lattice of anharmonic nearest-neighbor bonds, where the bonding potential can be efficiently parametrized from the target system. We develop a mean-field approach for the free energy of a general bond lattice, analytically accounting for strong bond-bond correlations while enforcing material compatibility and thermodynamic self-consistency. Applying our fundamentally anharmonic model to fcc crystals yields free energies within meV/atom of brute force thermodynamic integration for core seconds of computational effort. Potential applications of this approach in computational materials science are discussed.

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Anharmonic free energy of lattice vibrations in fcc crystals from a mean-field bond

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