A phase-field/fluid motion model of solidification: investigation of flow effects during directional solidification and dendritic growth
A phase-field/fluid motion model of solidification: investigation of flow effects during directional solidification and dendritic growth
The phase-field model of solidification is extended to include the effects of fluid flow in the melt. The phase-field model is based on coupling the nist-equations for heat flow in the liquid and solid phases with an auxiliary nist-equation that describes the evolution of the phase-field variable, which is a non-conserved order parameter indicating the local phase, solid or liquid, at each point of the material. The solid-liquid interface is then represented by a diffuse transition layer in which the phase-field variable changes rapidly between its values in the bulk phases. The model is extended to include fluid flow by a further coupling to the Navier-Stokes nist-equations. Preliminary studies have been performed for a model in which the solid phase is treated as a liquid of high viscosity compared to the liquid phase. The main coupling in the Navier-Stokes nist-equations is then through an additional term in the stress tensor that depends on the gradients of the phase-field variable, representing the effects of capillary forces within the diffuse interface.
367-381
National Aeronautical and Space Administration
Anderson, D.M.
8d7064b5-f7cd-4e54-9163-51892a9a272c
Boettinger, W.J.
15c73ade-477d-4f65-b1e6-c48e4a612f66
Wheeler, A.A.
eb831100-6e51-4674-878a-a2936ad04d73
McFadden, G.B.
56b0d29e-1cfb-4775-96d1-d32d50ea08d2
1998
Anderson, D.M.
8d7064b5-f7cd-4e54-9163-51892a9a272c
Boettinger, W.J.
15c73ade-477d-4f65-b1e6-c48e4a612f66
Wheeler, A.A.
eb831100-6e51-4674-878a-a2936ad04d73
McFadden, G.B.
56b0d29e-1cfb-4775-96d1-d32d50ea08d2
Anderson, D.M., Boettinger, W.J., Wheeler, A.A. and McFadden, G.B.
(1998)
A phase-field/fluid motion model of solidification: investigation of flow effects during directional solidification and dendritic growth.
In Proceedings of the Microgravity Materials Science Conference.
National Aeronautical and Space Administration.
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
The phase-field model of solidification is extended to include the effects of fluid flow in the melt. The phase-field model is based on coupling the nist-equations for heat flow in the liquid and solid phases with an auxiliary nist-equation that describes the evolution of the phase-field variable, which is a non-conserved order parameter indicating the local phase, solid or liquid, at each point of the material. The solid-liquid interface is then represented by a diffuse transition layer in which the phase-field variable changes rapidly between its values in the bulk phases. The model is extended to include fluid flow by a further coupling to the Navier-Stokes nist-equations. Preliminary studies have been performed for a model in which the solid phase is treated as a liquid of high viscosity compared to the liquid phase. The main coupling in the Navier-Stokes nist-equations is then through an additional term in the stress tensor that depends on the gradients of the phase-field variable, representing the effects of capillary forces within the diffuse interface.
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Published date: 1998
Venue - Dates:
Microgravity Materials Science Conference, NASA Marshall Space Flight Center, Huntsville, Alabama, 1998-07-13 - 1998-07-15
Identifiers
Local EPrints ID: 29095
URI: http://eprints.soton.ac.uk/id/eprint/29095
PURE UUID: 56902c54-7865-4890-9109-d4c3b2f2a6df
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Date deposited: 10 Jan 2007
Last modified: 11 Dec 2021 15:12
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Contributors
Author:
D.M. Anderson
Author:
W.J. Boettinger
Author:
A.A. Wheeler
Author:
G.B. McFadden
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