Strain energy analysis of screw dislocations in 4H-SiC by molecular dynamics

Takahiro Kawamura; Mitsutoshi Mizutani; Yasuyuki Suzuki; Yoshihiro Kangawa; Koichi Kakimoto

doi:10.7567/JJAP.55.031301

Strain energy analysis of screw dislocations in 4H-SiC by molecular dynamics

Takahiro Kawamura, Mitsutoshi Mizutani, Yasuyuki Suzuki, Yoshihiro Kangawa, Koichi Kakimoto

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

2 Citations (Scopus)

Abstract

We simulated screw dislocations with the Burgers vector parallel to the [0001] direction in 4H-SiC by a classical molecular dynamics method. A stable structure of an extended dislocation generated by the dissociation of a screw dislocation was identified by calculating the strain energy caused by dislocation cores and stacking faults. As a result, we conclude that the most expected structure of the extended dislocation is made of partial dislocations with the Burgers vector b = 1/2c + 1/2c (c is equal to the thickness of one period in the c-axis direction of 4H-SiC) and the stacking fault that is parallel to the a-plane, and that the distance between the dislocation cores is less than about 44Å.

Original language	English
Article number	031301
Journal	Japanese journal of applied physics
Volume	55
Issue number	3
DOIs	https://doi.org/10.7567/JJAP.55.031301
Publication status	Published - 2016 Mar
Externally published	Yes

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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title = "Strain energy analysis of screw dislocations in 4H-SiC by molecular dynamics",

abstract = "We simulated screw dislocations with the Burgers vector parallel to the [0001] direction in 4H-SiC by a classical molecular dynamics method. A stable structure of an extended dislocation generated by the dissociation of a screw dislocation was identified by calculating the strain energy caused by dislocation cores and stacking faults. As a result, we conclude that the most expected structure of the extended dislocation is made of partial dislocations with the Burgers vector b = 1/2c + 1/2c (c is equal to the thickness of one period in the c-axis direction of 4H-SiC) and the stacking fault that is parallel to the a-plane, and that the distance between the dislocation cores is less than about 44{\AA}.",

author = "Takahiro Kawamura and Mitsutoshi Mizutani and Yasuyuki Suzuki and Yoshihiro Kangawa and Koichi Kakimoto",

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T1 - Strain energy analysis of screw dislocations in 4H-SiC by molecular dynamics

AU - Kawamura, Takahiro

AU - Mizutani, Mitsutoshi

AU - Suzuki, Yasuyuki

AU - Kangawa, Yoshihiro

AU - Kakimoto, Koichi

PY - 2016/3

Y1 - 2016/3

N2 - We simulated screw dislocations with the Burgers vector parallel to the [0001] direction in 4H-SiC by a classical molecular dynamics method. A stable structure of an extended dislocation generated by the dissociation of a screw dislocation was identified by calculating the strain energy caused by dislocation cores and stacking faults. As a result, we conclude that the most expected structure of the extended dislocation is made of partial dislocations with the Burgers vector b = 1/2c + 1/2c (c is equal to the thickness of one period in the c-axis direction of 4H-SiC) and the stacking fault that is parallel to the a-plane, and that the distance between the dislocation cores is less than about 44Å.

AB - We simulated screw dislocations with the Burgers vector parallel to the [0001] direction in 4H-SiC by a classical molecular dynamics method. A stable structure of an extended dislocation generated by the dissociation of a screw dislocation was identified by calculating the strain energy caused by dislocation cores and stacking faults. As a result, we conclude that the most expected structure of the extended dislocation is made of partial dislocations with the Burgers vector b = 1/2c + 1/2c (c is equal to the thickness of one period in the c-axis direction of 4H-SiC) and the stacking fault that is parallel to the a-plane, and that the distance between the dislocation cores is less than about 44Å.

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Strain energy analysis of screw dislocations in 4H-SiC by molecular dynamics

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