Ubiquitous Spin-Orbit Coupling in a Screw Dislocation with High Spin Coherency

Lin Hu; Huaqing Huang; Zhengfei Wang; W. Jiang; Xiaojuan Ni; Yinong Zhou; V. Zielasek; M. G. Lagally; Bing Huang; Feng Liu

doi:10.1103/PhysRevLett.121.066401

Ubiquitous Spin-Orbit Coupling in a Screw Dislocation with High Spin Coherency

Lin Hu, Huaqing Huang, Zhengfei Wang, W. Jiang, Xiaojuan Ni, Yinong Zhou, V. Zielasek, M. G. Lagally, Bing Huang^*, Feng Liu

^*此作品的通讯作者

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32 引用（Scopus）

摘要

We theoretically demonstrate that screw dislocation (SD), a 1D topological defect widely present in semiconductors, exhibits ubiquitously a new form of spin-orbit coupling (SOC) effect. Differing from the widely known conventional 2D Rashba-Dresselhaus (RD) SOC effect that typically exists at surfaces or interfaces, the deep-level nature of SD-SOC states in semiconductors readily makes it an ideal SOC. Remarkably, the spin texture of 1D SD-SOC, pertaining to the inherent symmetry of SD, exhibits a significantly higher degree of spin coherency than the 2D RD-SOC. Moreover, the 1D SD-SOC can be tuned by ionicity in compound semiconductors to ideally suppress spin relaxation, as demonstrated by comparative first-principles calculations of SDs in Si/Ge, GaAs, and SiC. Our findings therefore open a new door to manipulating spin transport in semiconductors by taking advantage of an otherwise detrimental topological defect.

源语言	英语
文章编号	066401
期刊	Physical Review Letters
卷	121
期	6
DOI	https://doi.org/10.1103/PhysRevLett.121.066401
出版状态	已出版 - 6 8月 2018
已对外发布	是

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title = "Ubiquitous Spin-Orbit Coupling in a Screw Dislocation with High Spin Coherency",

abstract = "We theoretically demonstrate that screw dislocation (SD), a 1D topological defect widely present in semiconductors, exhibits ubiquitously a new form of spin-orbit coupling (SOC) effect. Differing from the widely known conventional 2D Rashba-Dresselhaus (RD) SOC effect that typically exists at surfaces or interfaces, the deep-level nature of SD-SOC states in semiconductors readily makes it an ideal SOC. Remarkably, the spin texture of 1D SD-SOC, pertaining to the inherent symmetry of SD, exhibits a significantly higher degree of spin coherency than the 2D RD-SOC. Moreover, the 1D SD-SOC can be tuned by ionicity in compound semiconductors to ideally suppress spin relaxation, as demonstrated by comparative first-principles calculations of SDs in Si/Ge, GaAs, and SiC. Our findings therefore open a new door to manipulating spin transport in semiconductors by taking advantage of an otherwise detrimental topological defect.",

author = "Lin Hu and Huaqing Huang and Zhengfei Wang and W. Jiang and Xiaojuan Ni and Yinong Zhou and V. Zielasek and Lagally, {M. G.} and Bing Huang and Feng Liu",

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AU - Hu, Lin

AU - Huang, Huaqing

AU - Wang, Zhengfei

AU - Jiang, W.

AU - Ni, Xiaojuan

AU - Zhou, Yinong

AU - Zielasek, V.

AU - Lagally, M. G.

AU - Huang, Bing

AU - Liu, Feng

PY - 2018/8/6

Y1 - 2018/8/6

N2 - We theoretically demonstrate that screw dislocation (SD), a 1D topological defect widely present in semiconductors, exhibits ubiquitously a new form of spin-orbit coupling (SOC) effect. Differing from the widely known conventional 2D Rashba-Dresselhaus (RD) SOC effect that typically exists at surfaces or interfaces, the deep-level nature of SD-SOC states in semiconductors readily makes it an ideal SOC. Remarkably, the spin texture of 1D SD-SOC, pertaining to the inherent symmetry of SD, exhibits a significantly higher degree of spin coherency than the 2D RD-SOC. Moreover, the 1D SD-SOC can be tuned by ionicity in compound semiconductors to ideally suppress spin relaxation, as demonstrated by comparative first-principles calculations of SDs in Si/Ge, GaAs, and SiC. Our findings therefore open a new door to manipulating spin transport in semiconductors by taking advantage of an otherwise detrimental topological defect.

AB - We theoretically demonstrate that screw dislocation (SD), a 1D topological defect widely present in semiconductors, exhibits ubiquitously a new form of spin-orbit coupling (SOC) effect. Differing from the widely known conventional 2D Rashba-Dresselhaus (RD) SOC effect that typically exists at surfaces or interfaces, the deep-level nature of SD-SOC states in semiconductors readily makes it an ideal SOC. Remarkably, the spin texture of 1D SD-SOC, pertaining to the inherent symmetry of SD, exhibits a significantly higher degree of spin coherency than the 2D RD-SOC. Moreover, the 1D SD-SOC can be tuned by ionicity in compound semiconductors to ideally suppress spin relaxation, as demonstrated by comparative first-principles calculations of SDs in Si/Ge, GaAs, and SiC. Our findings therefore open a new door to manipulating spin transport in semiconductors by taking advantage of an otherwise detrimental topological defect.

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Ubiquitous Spin-Orbit Coupling in a Screw Dislocation with High Spin Coherency

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