Quantum Spin-Valley Hall Kink States: From Concept to Materials Design

Tong Zhou; Shuguang Cheng; Michael Schleenvoigt; Peter Schüffelgen; Hua Jiang; Zhongqin Yang; Igor Žutić

doi:10.1103/PhysRevLett.127.116402

Quantum Spin-Valley Hall Kink States: From Concept to Materials Design

Tong Zhou
, Shuguang Cheng
, Michael Schleenvoigt
, Peter Schüffelgen
, Hua Jiang
, Zhongqin Yang
, Igor Žutić

Physics

SUNY Buffalo
Northwest University China
Jülich Research Centre
Soochow University
Fudan University

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

52 Scopus citations

Abstract

We propose a general and tunable platform to realize high-density arrays of quantum spin-valley Hall kink (QSVHK) states with spin-valley-momentum locking based on a two-dimensional hexagonal topological insulator. Through the analysis of Berry curvature and topological charge, the QSVHK states are found to be topologically protected by the valley-inversion and time-reversal symmetries. Remarkably, the conductance of QSVHK states remains quantized against both nonmagnetic short- and long-range and magnetic long-range disorder, verified by the Green-function calculations. Based on first-principles results and our fabricated samples, we show that QSVHK states, protected with a gap up to 287 meV, can be realized in bismuthene by alloy engineering, surface functionalization, or electric field, supporting nonvolatile applications of spin-valley filters, valves, and waveguides even at room temperature.

Original language	English
Article number	116402
Journal	Physical Review Letters
Volume	127
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.127.116402
State	Published - Sep 10 2021

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10.1103/PhysRevLett.127.116402

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title = "Quantum Spin-Valley Hall Kink States: From Concept to Materials Design",

abstract = "We propose a general and tunable platform to realize high-density arrays of quantum spin-valley Hall kink (QSVHK) states with spin-valley-momentum locking based on a two-dimensional hexagonal topological insulator. Through the analysis of Berry curvature and topological charge, the QSVHK states are found to be topologically protected by the valley-inversion and time-reversal symmetries. Remarkably, the conductance of QSVHK states remains quantized against both nonmagnetic short- and long-range and magnetic long-range disorder, verified by the Green-function calculations. Based on first-principles results and our fabricated samples, we show that QSVHK states, protected with a gap up to 287 meV, can be realized in bismuthene by alloy engineering, surface functionalization, or electric field, supporting nonvolatile applications of spin-valley filters, valves, and waveguides even at room temperature.",

author = "Tong Zhou and Shuguang Cheng and Michael Schleenvoigt and Peter Sch{\"u}ffelgen and Hua Jiang and Zhongqin Yang and Igor {\v Z}uti{\'c}",

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T2 - From Concept to Materials Design

AU - Zhou, Tong

AU - Cheng, Shuguang

AU - Schleenvoigt, Michael

AU - Schüffelgen, Peter

AU - Jiang, Hua

AU - Yang, Zhongqin

AU - Žutić, Igor

PY - 2021/9/10

Y1 - 2021/9/10

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AB - We propose a general and tunable platform to realize high-density arrays of quantum spin-valley Hall kink (QSVHK) states with spin-valley-momentum locking based on a two-dimensional hexagonal topological insulator. Through the analysis of Berry curvature and topological charge, the QSVHK states are found to be topologically protected by the valley-inversion and time-reversal symmetries. Remarkably, the conductance of QSVHK states remains quantized against both nonmagnetic short- and long-range and magnetic long-range disorder, verified by the Green-function calculations. Based on first-principles results and our fabricated samples, we show that QSVHK states, protected with a gap up to 287 meV, can be realized in bismuthene by alloy engineering, surface functionalization, or electric field, supporting nonvolatile applications of spin-valley filters, valves, and waveguides even at room temperature.

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Quantum Spin-Valley Hall Kink States: From Concept to Materials Design

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