Existence of needle crystals in local models of solidification
- 1 January 1986
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 33 (1) , 435-441
- https://doi.org/10.1103/physreva.33.435
Abstract
The way in which surface tension acts as a singular perturbation to destroy the continuous family of needle-crystal solutions of the steady-state growth equations is analyzed in detail for two local models of solidification. All calculations are performed in the limit of small surface tension or, equivalently, small velocity. The basic mathematical ideas are introduced in connection with a quasilinear, isotropic version of the geometrical model of Brower et al., in which case the continuous family of solutions disappears completely. The formalism is then applied to a simplified boundary-layer model with an anisotropic kinetic attachment coefficient. In the latter case, the solvability condition for the existence of needle crystals can be satisfied whenever the coefficient of anisotropy is arbitrarily small but nonzero.Keywords
This publication has 11 references indexed in Scilit:
- Solvability condition for needle crystals at large undercooling in a nonlocal model of solidificationPhysical Review A, 1986
- Geometrical models of interface evolution. II. Numerical simulationPhysical Review A, 1984
- Pattern Selection in Dendritic SolidificationPhysical Review Letters, 1984
- Geometrical models of interface evolutionPhysical Review A, 1984
- Boundary-layer model of pattern formation in solidificationPhysical Review A, 1984
- Dynamics of Interfacial Pattern FormationPhysical Review Letters, 1983
- Geometrical Approach to Moving-Interface DynamicsPhysical Review Letters, 1983
- Instabilities and pattern formation in crystal growthReviews of Modern Physics, 1980
- Self-Similar Solutions as Intermediate AsymptoticsAnnual Review of Fluid Mechanics, 1972
- Dendritic and spheroidal growthActa Metallurgica, 1961