The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale

The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale

The main objective of the present work is to build a model and analyze the dynamic evolution process of antiphase domain boundary (APDB) in FeAl alloy. The formation, evolution of APDB, long range order (LRO), the crystal structure transition, impact of temperature on LRO, are investigated. Comparisons with experiments proves that the model is competent for the dynamic investigation of APDB in microscopic scale and able to predict different boundary-types and their corresponding atoms distribution. The dynamic process shows that the initial distribution of premier micro domains determine the morphology of APDB. The morphological evolution of APDB significantly affects the quantity of APDB. The in situ observation shows that the crystal structure of a micro domain is altered by the APDB movement. The calculated LRO revealed that the atoms in Al-sublattice mainly contribute to the low order degree of FeAl at different temperatures.

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Main Authors: Wang,Kun, Wang,Yongxin, Cheng,Yanfeng
Format: Digital revista
Language:English
Published: ABM, ABC, ABPol 2018
Online Access:http://old.scielo.br/scielo.php?script=sci_arttext&pid=S1516-14392018000500228
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spelling oai:scielo:S1516-143920180005002282018-07-31The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic ScaleWang,KunWang,YongxinCheng,Yanfeng Antiphase domain boundary Dynamic evolution Phase field simulation FeAl The main objective of the present work is to build a model and analyze the dynamic evolution process of antiphase domain boundary (APDB) in FeAl alloy. The formation, evolution of APDB, long range order (LRO), the crystal structure transition, impact of temperature on LRO, are investigated. Comparisons with experiments proves that the model is competent for the dynamic investigation of APDB in microscopic scale and able to predict different boundary-types and their corresponding atoms distribution. The dynamic process shows that the initial distribution of premier micro domains determine the morphology of APDB. The morphological evolution of APDB significantly affects the quantity of APDB. The in situ observation shows that the crystal structure of a micro domain is altered by the APDB movement. The calculated LRO revealed that the atoms in Al-sublattice mainly contribute to the low order degree of FeAl at different temperatures.info:eu-repo/semantics/openAccessABM, ABC, ABPolMaterials Research v.21 n.5 20182018-01-01info:eu-repo/semantics/articletext/htmlhttp://old.scielo.br/scielo.php?script=sci_arttext&pid=S1516-14392018000500228en10.1590/1980-5373-mr-2017-1048
institution SCIELO
collection OJS
country Brasil
countrycode BR
component Revista
access En linea
databasecode rev-scielo-br
tag revista
region America del Sur
libraryname SciELO
language English
format Digital
author Wang,Kun
Wang,Yongxin
Cheng,Yanfeng
spellingShingle Wang,Kun
Wang,Yongxin
Cheng,Yanfeng
The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
author_facet Wang,Kun
Wang,Yongxin
Cheng,Yanfeng
author_sort Wang,Kun
title The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
title_short The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
title_full The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
title_fullStr The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
title_full_unstemmed The Formation and Dynamic Evolution of Antiphase Domain Boundary in FeAl Alloy: Computational Simulation in Atomic Scale
title_sort formation and dynamic evolution of antiphase domain boundary in feal alloy: computational simulation in atomic scale
description The main objective of the present work is to build a model and analyze the dynamic evolution process of antiphase domain boundary (APDB) in FeAl alloy. The formation, evolution of APDB, long range order (LRO), the crystal structure transition, impact of temperature on LRO, are investigated. Comparisons with experiments proves that the model is competent for the dynamic investigation of APDB in microscopic scale and able to predict different boundary-types and their corresponding atoms distribution. The dynamic process shows that the initial distribution of premier micro domains determine the morphology of APDB. The morphological evolution of APDB significantly affects the quantity of APDB. The in situ observation shows that the crystal structure of a micro domain is altered by the APDB movement. The calculated LRO revealed that the atoms in Al-sublattice mainly contribute to the low order degree of FeAl at different temperatures.
publisher ABM, ABC, ABPol
publishDate 2018
url http://old.scielo.br/scielo.php?script=sci_arttext&pid=S1516-14392018000500228
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AT wangyongxin theformationanddynamicevolutionofantiphasedomainboundaryinfealalloycomputationalsimulationinatomicscale
AT chengyanfeng theformationanddynamicevolutionofantiphasedomainboundaryinfealalloycomputationalsimulationinatomicscale
AT wangkun formationanddynamicevolutionofantiphasedomainboundaryinfealalloycomputationalsimulationinatomicscale
AT wangyongxin formationanddynamicevolutionofantiphasedomainboundaryinfealalloycomputationalsimulationinatomicscale
AT chengyanfeng formationanddynamicevolutionofantiphasedomainboundaryinfealalloycomputationalsimulationinatomicscale
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