Liquid state properties from first principles DFT calculations: Static properties
Abstract
In order to test the Vibration-Transit (V-T) theory of liquid dynamics, ab initio density functional theory (DFT) calculations of thermodynamic properties of Na and Cu are performed and compared with experimental data. The calculations are done for the crystal at T = 0 and T_m, and for the liquid at T_m. The key theoretical quantities for crystal and liquid are the structural potential and the dynamical matrix, both as function of volume. The theoretical equations are presented, as well as details of the DFT computations. The properties compared with experiment are the equilibrium volume, the isothermal bulk modulus, the internal energy and the entropy. The agreement of theory with experiment is uniformly good. Our primary conclusion is that the application of DFT to V-T theory is feasible, and the resulting liquid calculations achieve the same level of accuracy as does ab initio lattice dynamics for crystals. Moreover, given the well established reliability of DFT, the present results provide a significant confirmation of V-T theory itself.
Cite
@article{arxiv.1005.0586,
title = {Liquid state properties from first principles DFT calculations: Static properties},
author = {Nicolas Bock and Erik Holmstrom and Travis B. Peery and Raquel Lizarraga and Eric D. Chisolm and Giulia De Lorenzi-Venneri and Duane C. Wallace},
journal= {arXiv preprint arXiv:1005.0586},
year = {2010}
}
Comments
9 pages, 3 figures, 5 tables, edited to more closely match published version