The recently introduced classification of two-dimensional insulators in terms of topological crystalline in-variants has been applied so far to "obstructed" atomic insulators characterized by a mismatch between the centers of the electronic Wannier functions and the ionic positions. We extend this notion to quantum spin Hall insulators in which the ground state cannot be described in terms of time-reversal symmetric localized Wannier functions. A system equivalent to graphene in all its relevant electronic and topological properties except for a real-space obstruction is identified and studied via symmetry analysis as well as with density functional theory. The low-energy model comprises a local spin-orbit coupling and a nonlocal symmetry breaking potential, which turn out to be the essential ingredients for an obstructed quantum spin Hall insulator. An experimental fingerprint of the obstruction is then measured in a large-gap triangular quantum spin Hall material.

Philipp Eck, Carmine Ortix, Armando Consiglio, Jonas Erhardt, Maximilian Bauernfeind, Simon Moser, et al. (2022). Real-space obstruction in quantum spin Hall insulators. PHYSICAL REVIEW. B, 106(19), 1-15 [10.1103/physrevb.106.195143].

Real-space obstruction in quantum spin Hall insulators

Domenico Di Sante;
2022

Abstract

The recently introduced classification of two-dimensional insulators in terms of topological crystalline in-variants has been applied so far to "obstructed" atomic insulators characterized by a mismatch between the centers of the electronic Wannier functions and the ionic positions. We extend this notion to quantum spin Hall insulators in which the ground state cannot be described in terms of time-reversal symmetric localized Wannier functions. A system equivalent to graphene in all its relevant electronic and topological properties except for a real-space obstruction is identified and studied via symmetry analysis as well as with density functional theory. The low-energy model comprises a local spin-orbit coupling and a nonlocal symmetry breaking potential, which turn out to be the essential ingredients for an obstructed quantum spin Hall insulator. An experimental fingerprint of the obstruction is then measured in a large-gap triangular quantum spin Hall material.
2022
Philipp Eck, Carmine Ortix, Armando Consiglio, Jonas Erhardt, Maximilian Bauernfeind, Simon Moser, et al. (2022). Real-space obstruction in quantum spin Hall insulators. PHYSICAL REVIEW. B, 106(19), 1-15 [10.1103/physrevb.106.195143].
Philipp Eck; Carmine Ortix; Armando Consiglio; Jonas Erhardt; Maximilian Bauernfeind; Simon Moser; Ralph Claessen; Domenico Di Sante; Giorgio Sangiova...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/918770
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