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

^*Corresponding author for this work

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

33 Citations (Scopus)

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.

Original language	English
Article number	066401
Journal	Physical Review Letters
Volume	121
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevLett.121.066401
Publication status	Published - 6 Aug 2018
Externally published	Yes

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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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