Linking phase-field and atomistic simulations to model dendritic solidification in highly undercooled melts

Jean Bragard; Alain Karma; Youngyih H. Lee; Mathis Plapp

doi:10.1023/A:1015815928191

Linking phase-field and atomistic simulations to model dendritic solidification in highly undercooled melts

Jean Bragard
, Alain Karma
, Youngyih H. Lee
, Mathis Plapp

Northeastern University

Research output: Contribution to journal › Article › peer-review

Abstract

Even though our theoretical understanding of dendritic solidification is relatively well developed, our current ability to model this process quantitatively remains extremely limited. This is due to the fact that the morphological development of dendrites depends sensitively on the degree of anisotropy of capillary and/or kinetic properties of the solid-liquid interface, which is not precisely known for materials of metallurgical interest. Here we simulate the crystallization of highly undercooled nickel melts using a computationally efficient phase-field model together with anisotropic properties recently predicted by molecular dynamics simulations. The results are compared to experimental data and to the predictions of a linearized solvability theory that includes both capillary and kinetic effects at the interface.

Original language	English
Pages (from-to)	121-136
Number of pages	16
Journal	Interface Science
Volume	10
Issue number	2-3
DOIs	https://doi.org/10.1023/A:1015815928191
Publication status	Published - 1 Jul 2002

Keywords

Crystalline anisotropy
Dendrites
Interface kinetics
Metallic melts
Phase-field
Solidification

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10.1023/A:1015815928191

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title = "Linking phase-field and atomistic simulations to model dendritic solidification in highly undercooled melts",

abstract = "Even though our theoretical understanding of dendritic solidification is relatively well developed, our current ability to model this process quantitatively remains extremely limited. This is due to the fact that the morphological development of dendrites depends sensitively on the degree of anisotropy of capillary and/or kinetic properties of the solid-liquid interface, which is not precisely known for materials of metallurgical interest. Here we simulate the crystallization of highly undercooled nickel melts using a computationally efficient phase-field model together with anisotropic properties recently predicted by molecular dynamics simulations. The results are compared to experimental data and to the predictions of a linearized solvability theory that includes both capillary and kinetic effects at the interface.",

keywords = "Crystalline anisotropy, Dendrites, Interface kinetics, Metallic melts, Phase-field, Solidification",

author = "Jean Bragard and Alain Karma and Lee, \{Youngyih H.\} and Mathis Plapp",

year = "2002",

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doi = "10.1023/A:1015815928191",

language = "English",

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journal = "Interface Science",

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T1 - Linking phase-field and atomistic simulations to model dendritic solidification in highly undercooled melts

AU - Bragard, Jean

AU - Karma, Alain

AU - Lee, Youngyih H.

AU - Plapp, Mathis

PY - 2002/7/1

Y1 - 2002/7/1

N2 - Even though our theoretical understanding of dendritic solidification is relatively well developed, our current ability to model this process quantitatively remains extremely limited. This is due to the fact that the morphological development of dendrites depends sensitively on the degree of anisotropy of capillary and/or kinetic properties of the solid-liquid interface, which is not precisely known for materials of metallurgical interest. Here we simulate the crystallization of highly undercooled nickel melts using a computationally efficient phase-field model together with anisotropic properties recently predicted by molecular dynamics simulations. The results are compared to experimental data and to the predictions of a linearized solvability theory that includes both capillary and kinetic effects at the interface.

AB - Even though our theoretical understanding of dendritic solidification is relatively well developed, our current ability to model this process quantitatively remains extremely limited. This is due to the fact that the morphological development of dendrites depends sensitively on the degree of anisotropy of capillary and/or kinetic properties of the solid-liquid interface, which is not precisely known for materials of metallurgical interest. Here we simulate the crystallization of highly undercooled nickel melts using a computationally efficient phase-field model together with anisotropic properties recently predicted by molecular dynamics simulations. The results are compared to experimental data and to the predictions of a linearized solvability theory that includes both capillary and kinetic effects at the interface.

KW - Crystalline anisotropy

KW - Dendrites

KW - Interface kinetics

KW - Metallic melts

KW - Phase-field

KW - Solidification

U2 - 10.1023/A:1015815928191

DO - 10.1023/A:1015815928191

M3 - Article

AN - SCOPUS:0036641463

SN - 0927-7056

VL - 10

SP - 121

EP - 136

JO - Interface Science

JF - Interface Science

IS - 2-3

ER -

Linking phase-field and atomistic simulations to model dendritic solidification in highly undercooled melts

Abstract

Keywords

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