Spinodal decomposition of an ABv model alloy: Patterns at unstable surfaces

M. Plapp; J. F. Gouyet

doi:10.1007/s100510050766

Spinodal decomposition of an ABv model alloy: Patterns at unstable surfaces

M. Plapp
, J. F. Gouyet

Northeastern University

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

Abstract

We develop mean-field kinetic equations for a lattice gas model of a binary alloy with vacancies (ABv model) in which diffusion takes place by a vacancy mechanism. These equations are applied to the study of phase separation of finite portions of an unstable mixture immersed in a stable vapor. Due to a larger mobility of surface atoms, the most unstable modes of spinodal decomposition are localized at the vapor-mixture interface. Simulations show checkerboard-like structures at the surface or surface-directed spinodal waves. We determine the growth rates of bulk and surface modes by a linear stability analysis and deduce the relation between the parameters of the model and the structure and length scale of the surface patterns. The thickness of the surface patterns is related to the concentration fluctuations in the initial state.

Original language	English
Pages (from-to)	267-282
Number of pages	16
Journal	European Physical Journal B
Volume	9
Issue number	2
DOIs	https://doi.org/10.1007/s100510050766
Publication status	Published - 2 May 1999

Keywords

05.70.Ln Nonequilibrium and irreversible thermodynamics
64.75.+g Solubility, segregation, and mixing; phase separation
68.35.Fx Diffusion; interface formation

Access to Document

10.1007/s100510050766

Cite this

@article{34dee705c3bc404ba6d840d1e6dc639b,

title = "Spinodal decomposition of an ABv model alloy: Patterns at unstable surfaces",

abstract = "We develop mean-field kinetic equations for a lattice gas model of a binary alloy with vacancies (ABv model) in which diffusion takes place by a vacancy mechanism. These equations are applied to the study of phase separation of finite portions of an unstable mixture immersed in a stable vapor. Due to a larger mobility of surface atoms, the most unstable modes of spinodal decomposition are localized at the vapor-mixture interface. Simulations show checkerboard-like structures at the surface or surface-directed spinodal waves. We determine the growth rates of bulk and surface modes by a linear stability analysis and deduce the relation between the parameters of the model and the structure and length scale of the surface patterns. The thickness of the surface patterns is related to the concentration fluctuations in the initial state.",

keywords = "05.70.Ln Nonequilibrium and irreversible thermodynamics, 64.75.+g Solubility, segregation, and mixing; phase separation, 68.35.Fx Diffusion; interface formation",

author = "M. Plapp and Gouyet, \{J. F.\}",

year = "1999",

month = may,

day = "2",

doi = "10.1007/s100510050766",

language = "English",

volume = "9",

pages = "267--282",

journal = "European Physical Journal B",

issn = "1434-6028",

number = "2",

}

TY - JOUR

T1 - Spinodal decomposition of an ABv model alloy

T2 - Patterns at unstable surfaces

AU - Plapp, M.

AU - Gouyet, J. F.

PY - 1999/5/2

Y1 - 1999/5/2

N2 - We develop mean-field kinetic equations for a lattice gas model of a binary alloy with vacancies (ABv model) in which diffusion takes place by a vacancy mechanism. These equations are applied to the study of phase separation of finite portions of an unstable mixture immersed in a stable vapor. Due to a larger mobility of surface atoms, the most unstable modes of spinodal decomposition are localized at the vapor-mixture interface. Simulations show checkerboard-like structures at the surface or surface-directed spinodal waves. We determine the growth rates of bulk and surface modes by a linear stability analysis and deduce the relation between the parameters of the model and the structure and length scale of the surface patterns. The thickness of the surface patterns is related to the concentration fluctuations in the initial state.

AB - We develop mean-field kinetic equations for a lattice gas model of a binary alloy with vacancies (ABv model) in which diffusion takes place by a vacancy mechanism. These equations are applied to the study of phase separation of finite portions of an unstable mixture immersed in a stable vapor. Due to a larger mobility of surface atoms, the most unstable modes of spinodal decomposition are localized at the vapor-mixture interface. Simulations show checkerboard-like structures at the surface or surface-directed spinodal waves. We determine the growth rates of bulk and surface modes by a linear stability analysis and deduce the relation between the parameters of the model and the structure and length scale of the surface patterns. The thickness of the surface patterns is related to the concentration fluctuations in the initial state.

KW - 05.70.Ln Nonequilibrium and irreversible thermodynamics

KW - 64.75.+g Solubility, segregation, and mixing; phase separation

KW - 68.35.Fx Diffusion; interface formation

UR - https://www.scopus.com/pages/publications/0009936790

U2 - 10.1007/s100510050766

DO - 10.1007/s100510050766

M3 - Article

AN - SCOPUS:0009936790

SN - 1434-6028

VL - 9

SP - 267

EP - 282

JO - European Physical Journal B

JF - European Physical Journal B

IS - 2

ER -

Spinodal decomposition of an ABv model alloy: Patterns at unstable surfaces

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this