Nonequilibrium molecular dynamics simulation of rapid directional
  solidification

A. A. Wheeler; A. Karma; A. Karma; B. Billia; C. F. Richardson; D. Beeman; D. Frenkel; D. K. Chokappa; F. Ercolessi; F. F. Abraham; Franck Celestini; J. S. Rowlinson; J. W. Cahn; Jean-Marc Debierre; K. Kassner; K. W. Jacobsen; M. J. Aziz; M. J. P. Nijmeijer; M. R. Hitchcock; M. S. Daw; N. A. Ahmad; P. Z. Coura; R. F. Wood; R. F. Wood; R. F. Wood; X. Cottin

research

Nonequilibrium molecular dynamics simulation of rapid directional solidification

Authors: A. A. Wheeler
A. Karma
A. Karma
B. Billia
C. F. Richardson
D. Beeman
D. Frenkel
D. K. Chokappa
F. Ercolessi
F. F. Abraham
Franck Celestini
J. S. Rowlinson
J. W. Cahn
Jean-Marc Debierre
K. Kassner
K. W. Jacobsen
M. J. Aziz
M. J. P. Nijmeijer
M. R. Hitchcock
M. S. Daw
N. A. Ahmad
P. Z. Coura
R. F. Wood
R. F. Wood
R. F. Wood
X. Cottin
Publication date: 1 January 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We present the results of non-equilibrium molecular dynamics simulations for the growth of a solid binary alloy from its liquid phase. The regime of high pulling velocities,

V

, for which there is a progressive transition from solute segregation to solute trapping, is considered. In the segregation regime, we recover the exponential form of the concentration profile within the liquid phase. Solute trapping is shown to settle in progressively as

V

is increased and our results are in good agreement with the theoretical predictions of Aziz [J. Appl. Phys. {\bf 53}, 1158 (1981)]. In addition, the fluid advection velocity is shown to remain directly proportional to