Empirical tight-binding force model for molecular-dynamics simulation of Si
- 15 April 1989
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 39 (12) , 8586-8592
- https://doi.org/10.1103/physrevb.39.8586
Abstract
A scheme of molecular-dynamics simulation using the empirical tight-binding force model is proposed. The scheme allows the interatomic interactions involved in the molecular dynamics to be determined by first-principles total-energy and electronic-structure calculations without resorting to fitting experimental data. For a first application of the scheme we show that a very simple nearest-neighbor two-center empirical tight-binding force model is able to stabilize the diamond structure of Si within a reasonable temperature range. We also show that the scheme makes possible the quantitative calculation of the temperature dependence of various anharmonic effects such as lattice thermal expansion, temperature-dependent phonon linewidths, and phonon frequency shifts.Keywords
This publication has 20 references indexed in Scilit:
- Lattice Dynamics of Silicon with Empirical Many-Body PotentialsPhysical Review Letters, 1988
- Dispersion and dipole activity of surface phonons on Si(111) 2×1Physical Review B, 1988
- Structure and bonding of small semiconductor clustersPhysical Review B, 1987
- Surface reconstruction and vibrational excitations of Si(001)Physical Review B, 1987
- Development of a many-body Tersoff-type potential for siliconPhysical Review B, 1987
- Dissociative valence force field potential for siliconPhysical Review B, 1986
- Interatomic Potentials for Silicon Structural EnergiesPhysical Review Letters, 1985
- Stresses in semiconductors:Ab initiocalculations on Si, Ge, and GaAsPhysical Review B, 1985
- Theoretical study of the atomic structure of silicon (211), (311), and (331) surfacesPhysical Review B, 1984
- Theory of lattice-dynamical properties of solids: Application to Si and GePhysical Review B, 1982