Thermal Contraction and Disordering of the Al(110) Surface
- 19 April 1999
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 82 (16), 3296-3299
- https://doi.org/10.1103/physrevlett.82.3296
Abstract
Al(110) has been studied for temperatures up to 900 K via ensemble density-functional molecular dynamics. The strong anharmonicity displayed by this surface results in a negative coefficient of thermal expansion, where the first interlayer distance decreases with increasing temperature. Very shallow channels of oscillation for the second-layer atoms in the direction perpendicular to the surface support this anomalous contraction, and provide a novel mechanism for the formation of adatom-vacancy pairs, preliminary to the disordering and premelting transition. Such characteristic behavior originates in the free-electron-gas bonding at a loosely packed surface.All Related Versions
This publication has 29 references indexed in Scilit:
- Ensemble Density-Functional Theory forAb InitioMolecular Dynamics of Metals and Finite-Temperature InsulatorsPhysical Review Letters, 1997
- Partial Order of the Quasiliquid During Surface Melting of Al(110)Physical Review Letters, 1997
- Anisotropy of the stress on fcc(110) surfacesPhysical Review B, 1995
- Temperature dependence of interlayer spacings and mean vibrational amplitudes at the Al(110) surfacePhysical Review B, 1993
- Anharmonicity and disorder on the Cu(110) surfacePhysical Review B, 1991
- Pseudoenergies for simulations on metallic systemsPhysical Review B, 1991
- Investigation of multilayer relaxation on Al(110) with the use of self-consistent total-energy calculationsPhysical Review B, 1985
- Surface melting of copperPhysical Review B, 1985
- Truncation-induced multilayer relaxation of the A1(110) surfacePhysical Review B, 1984
- Oscillatory relaxation of the Al(110) surfaceJournal of Physics C: Solid State Physics, 1984