Atomistic simulation of the bcc-hcp transition in iron driven by uniaxial strain

Jian Li Shao; An Min He; Su Qing Duan; Pei Wang; Cheng Sen Qin

Atomistic simulation of the bcc-hcp transition in iron driven by uniaxial strain

Jian Li Shao^*, An Min He, Su Qing Duan, Pei Wang, Cheng Sen Qin

^*Corresponding author for this work

IAPCM

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

7 Citations (Scopus)

Abstract

The bcc-hcp structural transition in single crystal iron under <001> uniaxial strain has been investigated by molecular dynamics simulation. The reversibility and the morphological characteristics are discussed. The stress history indicates a super-elastic deformation in the sample, while the change of temperature shows the heat release during both hcp and bcc nucleation. A laminated structure of bcc and hcp along {011} planes is obtained, where the phase boundaries for the bcc to hcp and hcp to bcc transition are found along the same plane, implying the memory effect of morphology. Stacking faults (fcc) can be formed at the interface between hcp nuclei. For the bcc to hcp transition, we observed the mergence of the stacking faults in an hcp grain and the position adjustment between hcp grains. No migration of stacking fault is found during the hcp to bcc transition. In addition, the bcc-hcp transition structure is analyzed by the radial distribution function.

Original language	English
Pages (from-to)	4888-4894
Number of pages	7
Journal	Wuli Xuebao/Acta Physica Sinica
Volume	59
Issue number	7
Publication status	Published - Jul 2010
Externally published	Yes

Keywords

Iron
Molecular dynamics
Structural transition
Uniaxial strain

Cite this

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title = "Atomistic simulation of the bcc-hcp transition in iron driven by uniaxial strain",

abstract = "The bcc-hcp structural transition in single crystal iron under <001> uniaxial strain has been investigated by molecular dynamics simulation. The reversibility and the morphological characteristics are discussed. The stress history indicates a super-elastic deformation in the sample, while the change of temperature shows the heat release during both hcp and bcc nucleation. A laminated structure of bcc and hcp along {011} planes is obtained, where the phase boundaries for the bcc to hcp and hcp to bcc transition are found along the same plane, implying the memory effect of morphology. Stacking faults (fcc) can be formed at the interface between hcp nuclei. For the bcc to hcp transition, we observed the mergence of the stacking faults in an hcp grain and the position adjustment between hcp grains. No migration of stacking fault is found during the hcp to bcc transition. In addition, the bcc-hcp transition structure is analyzed by the radial distribution function.",

keywords = "Iron, Molecular dynamics, Structural transition, Uniaxial strain",

author = "Shao, {Jian Li} and He, {An Min} and Duan, {Su Qing} and Pei Wang and Qin, {Cheng Sen}",

year = "2010",

month = jul,

language = "English",

volume = "59",

pages = "4888--4894",

journal = "Wuli Xuebao/Acta Physica Sinica",

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TY - JOUR

T1 - Atomistic simulation of the bcc-hcp transition in iron driven by uniaxial strain

AU - Shao, Jian Li

AU - He, An Min

AU - Duan, Su Qing

AU - Wang, Pei

AU - Qin, Cheng Sen

PY - 2010/7

Y1 - 2010/7

N2 - The bcc-hcp structural transition in single crystal iron under <001> uniaxial strain has been investigated by molecular dynamics simulation. The reversibility and the morphological characteristics are discussed. The stress history indicates a super-elastic deformation in the sample, while the change of temperature shows the heat release during both hcp and bcc nucleation. A laminated structure of bcc and hcp along {011} planes is obtained, where the phase boundaries for the bcc to hcp and hcp to bcc transition are found along the same plane, implying the memory effect of morphology. Stacking faults (fcc) can be formed at the interface between hcp nuclei. For the bcc to hcp transition, we observed the mergence of the stacking faults in an hcp grain and the position adjustment between hcp grains. No migration of stacking fault is found during the hcp to bcc transition. In addition, the bcc-hcp transition structure is analyzed by the radial distribution function.

AB - The bcc-hcp structural transition in single crystal iron under <001> uniaxial strain has been investigated by molecular dynamics simulation. The reversibility and the morphological characteristics are discussed. The stress history indicates a super-elastic deformation in the sample, while the change of temperature shows the heat release during both hcp and bcc nucleation. A laminated structure of bcc and hcp along {011} planes is obtained, where the phase boundaries for the bcc to hcp and hcp to bcc transition are found along the same plane, implying the memory effect of morphology. Stacking faults (fcc) can be formed at the interface between hcp nuclei. For the bcc to hcp transition, we observed the mergence of the stacking faults in an hcp grain and the position adjustment between hcp grains. No migration of stacking fault is found during the hcp to bcc transition. In addition, the bcc-hcp transition structure is analyzed by the radial distribution function.

KW - Iron

KW - Molecular dynamics

KW - Structural transition

KW - Uniaxial strain

UR - http://www.scopus.com/inward/record.url?scp=77955319442&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:77955319442

SN - 1000-3290

VL - 59

SP - 4888

EP - 4894

JO - Wuli Xuebao/Acta Physica Sinica

JF - Wuli Xuebao/Acta Physica Sinica

IS - 7

ER -

Atomistic simulation of the bcc-hcp transition in iron driven by uniaxial strain

Abstract

Keywords

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