Quantum spin Hall phase in GeSn heterostructures on silicon

B. M. Ferrari; F. Marcantonio; F. Murphy-Armando; M. Virgilio; F. Pezzoli

doi:10.1103/PhysRevResearch.5.L022035

Quantum spin Hall phase in GeSn heterostructures on silicon

B. M. Ferrari
, F. Marcantonio
, F. Murphy-Armando
, M. Virgilio
, F. Pezzoli

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

Abstract

Quantum phases of solid-state electron systems can sustain exotic phenomena and a very rich spin physics. We utilize model-solid theory to show that Ge1-xSnx alloys, an emerging group IV semiconductor, can be engineered into heterostructures that demonstrate a broken-gap alignment. Furthermore, the eight-band k·p method is used to disclose a quantum spin Hall phase in heterojunctions that accommodates the existence of gate-controlled chiral edge states. This proposal introduces a practical silicon-based architecture that spontaneously sustains topological properties, while being compatible with the high-volume manufacture of semiconductor technologies.

Original language	English
Article number	L022035
Journal	Physical Review Research
Volume	5
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevResearch.5.L022035
Publication status	Published - Apr 2023

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10.1103/PhysRevResearch.5.L022035

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title = "Quantum spin Hall phase in GeSn heterostructures on silicon",

abstract = "Quantum phases of solid-state electron systems can sustain exotic phenomena and a very rich spin physics. We utilize model-solid theory to show that Ge1-xSnx alloys, an emerging group IV semiconductor, can be engineered into heterostructures that demonstrate a broken-gap alignment. Furthermore, the eight-band k·p method is used to disclose a quantum spin Hall phase in heterojunctions that accommodates the existence of gate-controlled chiral edge states. This proposal introduces a practical silicon-based architecture that spontaneously sustains topological properties, while being compatible with the high-volume manufacture of semiconductor technologies.",

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AU - Ferrari, B. M.

AU - Marcantonio, F.

AU - Murphy-Armando, F.

AU - Virgilio, M.

AU - Pezzoli, F.

N1 - Publisher Copyright: © 2023 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

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N2 - Quantum phases of solid-state electron systems can sustain exotic phenomena and a very rich spin physics. We utilize model-solid theory to show that Ge1-xSnx alloys, an emerging group IV semiconductor, can be engineered into heterostructures that demonstrate a broken-gap alignment. Furthermore, the eight-band k·p method is used to disclose a quantum spin Hall phase in heterojunctions that accommodates the existence of gate-controlled chiral edge states. This proposal introduces a practical silicon-based architecture that spontaneously sustains topological properties, while being compatible with the high-volume manufacture of semiconductor technologies.

AB - Quantum phases of solid-state electron systems can sustain exotic phenomena and a very rich spin physics. We utilize model-solid theory to show that Ge1-xSnx alloys, an emerging group IV semiconductor, can be engineered into heterostructures that demonstrate a broken-gap alignment. Furthermore, the eight-band k·p method is used to disclose a quantum spin Hall phase in heterojunctions that accommodates the existence of gate-controlled chiral edge states. This proposal introduces a practical silicon-based architecture that spontaneously sustains topological properties, while being compatible with the high-volume manufacture of semiconductor technologies.

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DO - 10.1103/PhysRevResearch.5.L022035

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VL - 5

JO - Physical Review Research

JF - Physical Review Research

IS - 2

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ER -

Quantum spin Hall phase in GeSn heterostructures on silicon

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