Crystal-melt interfacial free energies and mobilities in fcc and bcc Fe

D. Y. Sun; M. Asta; J. J. Hoyt

doi:10.1103/PhysRevB.69.174103

Crystal-melt interfacial free energies and mobilities in fcc and bcc Fe

D. Y. Sun^*
, M. Asta
, J. J. Hoyt

^*Corresponding author for this work

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

183 Scopus citations

Abstract

Molecular-dynamics simulations have been used to compute thermodynamic and kinetic properties of the solid-liquid interface for both the fcc and bcc phases of Fe. Pure Fe was modeled using two different interatomic potentials of the embedded atom type as well as an effective pair potential. Free solidification simulations were used to determine the kinetic coefficient μ for the different models of pure Fe. The anisotropy of μ with respect to growth direction in the bcc phase is similar to that observed in fcc systems, namely μ₁₀₀ >μ₁₁₀∼μ₁₁₁, and the kinetic coefficient of bcc is larger than μ for the fcc phase. The kinetic coefficient results are discussed in terms of a kinetic density-functional- theory-based model of crystal growth. In addition, results for solid-liquid interfacial free energies y computed via the capillary fluctuation method, are summarized.

Original language	English
Article number	174103
Pages (from-to)	174103-1-174103-9
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	69
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevB.69.174103
State	Published - May 2004
Externally published	Yes

Access to Document

10.1103/PhysRevB.69.174103

Cite this

@article{b854e126e7ee4bc6b91c416e4bbe36c1,

title = "Crystal-melt interfacial free energies and mobilities in fcc and bcc Fe",

abstract = "Molecular-dynamics simulations have been used to compute thermodynamic and kinetic properties of the solid-liquid interface for both the fcc and bcc phases of Fe. Pure Fe was modeled using two different interatomic potentials of the embedded atom type as well as an effective pair potential. Free solidification simulations were used to determine the kinetic coefficient μ for the different models of pure Fe. The anisotropy of μ with respect to growth direction in the bcc phase is similar to that observed in fcc systems, namely μ100 >μ110∼μ111, and the kinetic coefficient of bcc is larger than μ for the fcc phase. The kinetic coefficient results are discussed in terms of a kinetic density-functional- theory-based model of crystal growth. In addition, results for solid-liquid interfacial free energies y computed via the capillary fluctuation method, are summarized.",

author = "Sun, \{D. Y.\} and M. Asta and Hoyt, \{J. J.\}",

year = "2004",

month = may,

doi = "10.1103/PhysRevB.69.174103",

language = "英语",

volume = "69",

pages = "174103--1--174103--9",

journal = "Physical Review B - Condensed Matter and Materials Physics",

issn = "0163-1829",

publisher = "American Physical Society",

number = "17",

}

TY - JOUR

T1 - Crystal-melt interfacial free energies and mobilities in fcc and bcc Fe

AU - Sun, D. Y.

AU - Asta, M.

AU - Hoyt, J. J.

PY - 2004/5

Y1 - 2004/5

N2 - Molecular-dynamics simulations have been used to compute thermodynamic and kinetic properties of the solid-liquid interface for both the fcc and bcc phases of Fe. Pure Fe was modeled using two different interatomic potentials of the embedded atom type as well as an effective pair potential. Free solidification simulations were used to determine the kinetic coefficient μ for the different models of pure Fe. The anisotropy of μ with respect to growth direction in the bcc phase is similar to that observed in fcc systems, namely μ100 >μ110∼μ111, and the kinetic coefficient of bcc is larger than μ for the fcc phase. The kinetic coefficient results are discussed in terms of a kinetic density-functional- theory-based model of crystal growth. In addition, results for solid-liquid interfacial free energies y computed via the capillary fluctuation method, are summarized.

AB - Molecular-dynamics simulations have been used to compute thermodynamic and kinetic properties of the solid-liquid interface for both the fcc and bcc phases of Fe. Pure Fe was modeled using two different interatomic potentials of the embedded atom type as well as an effective pair potential. Free solidification simulations were used to determine the kinetic coefficient μ for the different models of pure Fe. The anisotropy of μ with respect to growth direction in the bcc phase is similar to that observed in fcc systems, namely μ100 >μ110∼μ111, and the kinetic coefficient of bcc is larger than μ for the fcc phase. The kinetic coefficient results are discussed in terms of a kinetic density-functional- theory-based model of crystal growth. In addition, results for solid-liquid interfacial free energies y computed via the capillary fluctuation method, are summarized.

UR - https://www.scopus.com/pages/publications/42749103103

U2 - 10.1103/PhysRevB.69.174103

DO - 10.1103/PhysRevB.69.174103

M3 - 文章

AN - SCOPUS:42749103103

SN - 0163-1829

VL - 69

SP - 174103-1-174103-9

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 17

M1 - 174103

ER -

Crystal-melt interfacial free energies and mobilities in fcc and bcc Fe

Abstract

Access to Document

Other files and links

Fingerprint

Cite this