Phase-Field Formulation for Quantitative Modeling of Alloy
  Solidification

A. A. Wheeler; A. A. Wheeler; A. Karma; A. Karma; A. Karma; Alain Karma; G. B. McFadden; G. Caginalp; G. Caginalp; J. A. Warren; J. B. Collins; J. S. Langer; J. Tiaden; M. Plapp; M. Plapp; N. Provatas; N. Provatas; P. C. Fife; P. G. Saffman; R. F. Almgren; R. Folch; S. Osher; S.-G. Kim; W. Kurz; Y.-T. Kim

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Phase-Field Formulation for Quantitative Modeling of Alloy Solidification

Authors: A. A. Wheeler
A. A. Wheeler
A. Karma
A. Karma
A. Karma
Alain Karma
G. B. McFadden
G. Caginalp
G. Caginalp
J. A. Warren
J. B. Collins
J. S. Langer
J. Tiaden
M. Plapp
M. Plapp
N. Provatas
N. Provatas
P. C. Fife
P. G. Saffman
R. F. Almgren
R. Folch
S. Osher
S.-G. Kim
W. Kurz
Y.-T. Kim
Publication date: 1 January 2001
Publisher: 'American Physical Society (APS)'
Doi

Abstract

A phase-field formulation is introduced to simulate quantitatively microstructural pattern formation in alloys. The thin-interface limit of this formulation yields a much less stringent restriction on the choice of interface thickness than previous formulations and permits to eliminate non-equilibrium effects at the interface. Dendrite growth simulations with vanishing solid diffusivity show that both the interface evolution and the solute profile in the solid are well resolved

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