Quantum Spin Hall States and Topological Phase Transition in Germanene

Pantelis Bampoulis; Carolien Castenmiller; Dennis J. Klaassen; Jelle Van Mil; Yichen Liu; Cheng Cheng Liu; Yugui Yao; Motohiko Ezawa; Alexander N. Rudenko; Harold J.W. Zandvliet

doi:10.1103/PhysRevLett.130.196401

Quantum Spin Hall States and Topological Phase Transition in Germanene

Pantelis Bampoulis, Carolien Castenmiller, Dennis J. Klaassen, Jelle Van Mil, Yichen Liu, Cheng Cheng Liu, Yugui Yao, Motohiko Ezawa, Alexander N. Rudenko, Harold J.W. Zandvliet

物理学院

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45 引用（Scopus）

摘要

We present the first experimental evidence of a topological phase transition in a monoelemental quantum spin Hall insulator. Particularly, we show that low-buckled epitaxial germanene is a quantum spin Hall insulator with a large bulk gap and robust metallic edges. Applying a critical perpendicular electric field closes the topological gap and makes germanene a Dirac semimetal. Increasing the electric field further results in the opening of a trivial gap and disappearance of the metallic edge states. This electric field-induced switching of the topological state and the sizable gap make germanene suitable for room-temperature topological field-effect transistors, which could revolutionize low-energy electronics.

源语言	英语
文章编号	196401
期刊	Physical Review Letters
卷	130
期	19
DOI	https://doi.org/10.1103/PhysRevLett.130.196401
出版状态	已出版 - 12 5月 2023

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abstract = "We present the first experimental evidence of a topological phase transition in a monoelemental quantum spin Hall insulator. Particularly, we show that low-buckled epitaxial germanene is a quantum spin Hall insulator with a large bulk gap and robust metallic edges. Applying a critical perpendicular electric field closes the topological gap and makes germanene a Dirac semimetal. Increasing the electric field further results in the opening of a trivial gap and disappearance of the metallic edge states. This electric field-induced switching of the topological state and the sizable gap make germanene suitable for room-temperature topological field-effect transistors, which could revolutionize low-energy electronics.",

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AU - Bampoulis, Pantelis

AU - Castenmiller, Carolien

AU - Klaassen, Dennis J.

AU - Van Mil, Jelle

AU - Liu, Yichen

AU - Liu, Cheng Cheng

AU - Yao, Yugui

AU - Ezawa, Motohiko

AU - Rudenko, Alexander N.

AU - Zandvliet, Harold J.W.

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N2 - We present the first experimental evidence of a topological phase transition in a monoelemental quantum spin Hall insulator. Particularly, we show that low-buckled epitaxial germanene is a quantum spin Hall insulator with a large bulk gap and robust metallic edges. Applying a critical perpendicular electric field closes the topological gap and makes germanene a Dirac semimetal. Increasing the electric field further results in the opening of a trivial gap and disappearance of the metallic edge states. This electric field-induced switching of the topological state and the sizable gap make germanene suitable for room-temperature topological field-effect transistors, which could revolutionize low-energy electronics.

AB - We present the first experimental evidence of a topological phase transition in a monoelemental quantum spin Hall insulator. Particularly, we show that low-buckled epitaxial germanene is a quantum spin Hall insulator with a large bulk gap and robust metallic edges. Applying a critical perpendicular electric field closes the topological gap and makes germanene a Dirac semimetal. Increasing the electric field further results in the opening of a trivial gap and disappearance of the metallic edge states. This electric field-induced switching of the topological state and the sizable gap make germanene suitable for room-temperature topological field-effect transistors, which could revolutionize low-energy electronics.

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Quantum Spin Hall States and Topological Phase Transition in Germanene

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