Dynamics of phase separation of crystal surfaces
- 1 September 1993
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 48 (9) , 5808-5817
- https://doi.org/10.1103/physrevb.48.5808
Abstract
We investigate the dynamical evolution of a thermodynamically unstable crystal surface into a hill-and-valley structure. We demonstrate that, for quasi-one-dimensional ordering, the equation of motion maps exactly to the modified Cahn-Hilliard equation describing spinodal decomposition. Orderings in two dimensions follow the dynamics of continuum clock models. We establish that the hill-and-valley pattern coarsens logarithmically in time for quasi-one-dimensional orderings. For two-dimensional orderings, a power-law growth L(t)∼ of the typical pattern size is attained with exponent n≊0.23 and n≊0.13, for the two ordering mechanisms dominated by evaporation and condensation and by surface diffusion, respectively.
Keywords
All Related Versions
This publication has 28 references indexed in Scilit:
- Phase-ordering dynamics in the continuumq-state clock modelPhysical Review B, 1993
- Logarithmically slow domain growth in nonrandomly frustrated systems: Ising models with competing interactionsPhysical Review B, 1992
- Spinodal decomposition of a crystal surfacePhysical Review A, 1992
- Low-energy electron-microscopy investigations of orientational phase separation on vicinal Si(111) surfacesPhysical Review Letters, 1991
- Thermodynamics of Surface MorphologyScience, 1991
- Front migration in the nonlinear Cahn-Hilliard equationProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1989
- Defect-phase-dynamics approach to statistical domain-growth problem of clock modelsPhysical Review A, 1985
- Quantitative evaluation of evaporation structures of {100}, {110}, and {111}NaCl surfaces annealed in a vacuum between 400 and 800°CJournal of Crystal Growth, 1977
- Flattening of a Nearly Plane Solid Surface due to CapillarityJournal of Applied Physics, 1959
- Theory of Thermal GroovingJournal of Applied Physics, 1957