Tunable quantum order in bilayer Bi2Te3: Stacking dependent quantum spin Hall states

Liangzhi Kou; Chengwang Niu; Huixia Fu; Yandong Ma; Binghai Yan; Changfeng Chen

doi:10.1063/1.5038079

Tunable quantum order in bilayer Bi₂Te₃: Stacking dependent quantum spin Hall states

Liangzhi Kou, Chengwang Niu, Huixia Fu, Yandong Ma, Binghai Yan, Changfeng Chen

Physics

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

8 Scopus citations

Abstract

Recent years have seen the rising importance of interface stacking in determining the electronic properties of multilayer materials stemming from the interlayer coupling; however, the stacking effects on exotic topological quantum orders largely remain to be explored. Here, we show by first-principles studies that bilayer Bi₂Te₃ host stacking is dependent on quantum spin Hall effects, with a topological phase transition induced by a change in the interlayer stacking pattern. The spin-filtered helical edge states are concomitantly switched on/off along with the changing interlayer stacking pattern. Since few-layer Bi2Te₃ has already been experimentally synthesized, the present finding opens an avenue for exploring the fundamental mechanisms and the practical implications of the quantum phenomena associated with band topology in this versatile and intriguing 2D material.

Original language	English (US)
Article number	243103
Journal	Applied Physics Letters
Volume	112
Issue number	24
DOIs	https://doi.org/10.1063/1.5038079
State	Published - Jun 11 2018

All Science Journal Classification (ASJC) codes

Physics and Astronomy (miscellaneous)

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10.1063/1.5038079

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title = "Tunable quantum order in bilayer Bi2Te3: Stacking dependent quantum spin Hall states",

abstract = "Recent years have seen the rising importance of interface stacking in determining the electronic properties of multilayer materials stemming from the interlayer coupling; however, the stacking effects on exotic topological quantum orders largely remain to be explored. Here, we show by first-principles studies that bilayer Bi2Te3 host stacking is dependent on quantum spin Hall effects, with a topological phase transition induced by a change in the interlayer stacking pattern. The spin-filtered helical edge states are concomitantly switched on/off along with the changing interlayer stacking pattern. Since few-layer Bi2Te3 has already been experimentally synthesized, the present finding opens an avenue for exploring the fundamental mechanisms and the practical implications of the quantum phenomena associated with band topology in this versatile and intriguing 2D material.",

author = "Liangzhi Kou and Chengwang Niu and Huixia Fu and Yandong Ma and Binghai Yan and Changfeng Chen",

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T1 - Tunable quantum order in bilayer Bi2Te3

T2 - Stacking dependent quantum spin Hall states

AU - Kou, Liangzhi

AU - Niu, Chengwang

AU - Fu, Huixia

AU - Ma, Yandong

AU - Yan, Binghai

AU - Chen, Changfeng

PY - 2018/6/11

Y1 - 2018/6/11

N2 - Recent years have seen the rising importance of interface stacking in determining the electronic properties of multilayer materials stemming from the interlayer coupling; however, the stacking effects on exotic topological quantum orders largely remain to be explored. Here, we show by first-principles studies that bilayer Bi2Te3 host stacking is dependent on quantum spin Hall effects, with a topological phase transition induced by a change in the interlayer stacking pattern. The spin-filtered helical edge states are concomitantly switched on/off along with the changing interlayer stacking pattern. Since few-layer Bi2Te3 has already been experimentally synthesized, the present finding opens an avenue for exploring the fundamental mechanisms and the practical implications of the quantum phenomena associated with band topology in this versatile and intriguing 2D material.

AB - Recent years have seen the rising importance of interface stacking in determining the electronic properties of multilayer materials stemming from the interlayer coupling; however, the stacking effects on exotic topological quantum orders largely remain to be explored. Here, we show by first-principles studies that bilayer Bi2Te3 host stacking is dependent on quantum spin Hall effects, with a topological phase transition induced by a change in the interlayer stacking pattern. The spin-filtered helical edge states are concomitantly switched on/off along with the changing interlayer stacking pattern. Since few-layer Bi2Te3 has already been experimentally synthesized, the present finding opens an avenue for exploring the fundamental mechanisms and the practical implications of the quantum phenomena associated with band topology in this versatile and intriguing 2D material.

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Tunable quantum order in bilayer Bi₂Te₃: Stacking dependent quantum spin Hall states

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