Orbital Shift-Induced Boundary Obstructed Topological Materials with a Large Energy Gap

Ning Mao; Runhan Li; Ying Dai; Baibiao Huang; Binghai Yan; Chengwang Niu

doi:10.1002/advs.202202564

Orbital Shift-Induced Boundary Obstructed Topological Materials with a Large Energy Gap

Ning Mao, Runhan Li, Ying Dai, Baibiao Huang, Binghai Yan, Chengwang Niu

Department of Condensed Matter Physics

Weizmann Institute of Science

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

Abstract

Boundary obstructed topological phases caused by Wannier orbital shift between ordinary atomic sites are proposed, which, however, cannot be indicated by symmetry eigenvalues at high symmetry momenta (symmetry indicators) in bulk. On the open boundary, Wannier charge centers can shift to different atoms from those in bulk, leading to in-gap surface states, higher-order hinge states or corner states. To demonstrate such orbital shift-induced boundary obstructed topological insulators, eight material candidates are predicted, all of which are overlooked in the present topological databases. Metallic surface states, hinge states, or corner states cover the large bulk energy gap (e.g., more than 1 eV in TlGaTe2) at related boundary, which are ready for experimental detection. Additionally, these materials are also fragile topological insulators with hourglass-like surface states.

Original language	English
Article number	2202564
Journal	Advanced Science
Volume	9
Issue number	27
Early online date	29 Jul 2022
DOIs	https://doi.org/10.1002/advs.202202564
State	Published - 23 Sep 2022

All Science Journal Classification (ASJC) codes

Medicine (miscellaneous)
General Chemical Engineering
General Materials Science
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Engineering
General Physics and Astronomy

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Cite this

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title = "Orbital Shift-Induced Boundary Obstructed Topological Materials with a Large Energy Gap",

abstract = "Boundary obstructed topological phases caused by Wannier orbital shift between ordinary atomic sites are proposed, which, however, cannot be indicated by symmetry eigenvalues at high symmetry momenta (symmetry indicators) in bulk. On the open boundary, Wannier charge centers can shift to different atoms from those in bulk, leading to in-gap surface states, higher-order hinge states or corner states. To demonstrate such orbital shift-induced boundary obstructed topological insulators, eight material candidates are predicted, all of which are overlooked in the present topological databases. Metallic surface states, hinge states, or corner states cover the large bulk energy gap (e.g., more than 1 eV in TlGaTe2) at related boundary, which are ready for experimental detection. Additionally, these materials are also fragile topological insulators with hourglass-like surface states.",

author = "Ning Mao and Runhan Li and Ying Dai and Baibiao Huang and Binghai Yan and Chengwang Niu",

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AU - Mao, Ning

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AU - Yan, Binghai

AU - Niu, Chengwang

PY - 2022/9/23

Y1 - 2022/9/23

N2 - Boundary obstructed topological phases caused by Wannier orbital shift between ordinary atomic sites are proposed, which, however, cannot be indicated by symmetry eigenvalues at high symmetry momenta (symmetry indicators) in bulk. On the open boundary, Wannier charge centers can shift to different atoms from those in bulk, leading to in-gap surface states, higher-order hinge states or corner states. To demonstrate such orbital shift-induced boundary obstructed topological insulators, eight material candidates are predicted, all of which are overlooked in the present topological databases. Metallic surface states, hinge states, or corner states cover the large bulk energy gap (e.g., more than 1 eV in TlGaTe2) at related boundary, which are ready for experimental detection. Additionally, these materials are also fragile topological insulators with hourglass-like surface states.

AB - Boundary obstructed topological phases caused by Wannier orbital shift between ordinary atomic sites are proposed, which, however, cannot be indicated by symmetry eigenvalues at high symmetry momenta (symmetry indicators) in bulk. On the open boundary, Wannier charge centers can shift to different atoms from those in bulk, leading to in-gap surface states, higher-order hinge states or corner states. To demonstrate such orbital shift-induced boundary obstructed topological insulators, eight material candidates are predicted, all of which are overlooked in the present topological databases. Metallic surface states, hinge states, or corner states cover the large bulk energy gap (e.g., more than 1 eV in TlGaTe2) at related boundary, which are ready for experimental detection. Additionally, these materials are also fragile topological insulators with hourglass-like surface states.

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Orbital Shift-Induced Boundary Obstructed Topological Materials with a Large Energy Gap

Abstract

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