Chiral one-dimensional Floquet topological insulators beyond the rotating wave approximation

Dante M. Kennes; Niclas Müller; Mikhail Pletyukhov; Clara Weber; Christoph Bruder; Fabian Hassler; Jelena Klinovaja; Daniel Loss; Herbert Schoeller

doi:10.1103/PhysRevB.100.041103

Chiral one-dimensional Floquet topological insulators beyond the rotating wave approximation

Dante M. Kennes, Niclas Müller, Mikhail Pletyukhov, Clara Weber, Christoph Bruder, Fabian Hassler, Jelena Klinovaja, Daniel Loss, Herbert Schoeller

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

21 Scopus citations

Abstract

We study one-dimensional Floquet topological insulators with chiral symmetry going beyond the standard rotating wave approximation. The occurrence of many anticrossings between Floquet replicas leads to a dramatic extension of phase diagram regions with stable topological edge states (TESs). We present an explicit construction of all TESs in terms of a truncated Floquet Hamiltonian in frequency space, prove the bulk-boundary correspondence, and analyze the stability of the TESs in terms of their localization lengths. We propose experimental tests of our predictions in curved bilayer graphene.

Original language	English
Article number	041103
Journal	Physical Review B
Volume	100
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.100.041103
State	Published - 3 Jul 2019
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2019 American Physical Society.

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.100.041103

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abstract = "We study one-dimensional Floquet topological insulators with chiral symmetry going beyond the standard rotating wave approximation. The occurrence of many anticrossings between Floquet replicas leads to a dramatic extension of phase diagram regions with stable topological edge states (TESs). We present an explicit construction of all TESs in terms of a truncated Floquet Hamiltonian in frequency space, prove the bulk-boundary correspondence, and analyze the stability of the TESs in terms of their localization lengths. We propose experimental tests of our predictions in curved bilayer graphene.",

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AU - Kennes, Dante M.

AU - Müller, Niclas

AU - Pletyukhov, Mikhail

AU - Weber, Clara

AU - Bruder, Christoph

AU - Hassler, Fabian

AU - Klinovaja, Jelena

AU - Loss, Daniel

AU - Schoeller, Herbert

PY - 2019/7/3

Y1 - 2019/7/3

N2 - We study one-dimensional Floquet topological insulators with chiral symmetry going beyond the standard rotating wave approximation. The occurrence of many anticrossings between Floquet replicas leads to a dramatic extension of phase diagram regions with stable topological edge states (TESs). We present an explicit construction of all TESs in terms of a truncated Floquet Hamiltonian in frequency space, prove the bulk-boundary correspondence, and analyze the stability of the TESs in terms of their localization lengths. We propose experimental tests of our predictions in curved bilayer graphene.

AB - We study one-dimensional Floquet topological insulators with chiral symmetry going beyond the standard rotating wave approximation. The occurrence of many anticrossings between Floquet replicas leads to a dramatic extension of phase diagram regions with stable topological edge states (TESs). We present an explicit construction of all TESs in terms of a truncated Floquet Hamiltonian in frequency space, prove the bulk-boundary correspondence, and analyze the stability of the TESs in terms of their localization lengths. We propose experimental tests of our predictions in curved bilayer graphene.

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ER -

Chiral one-dimensional Floquet topological insulators beyond the rotating wave approximation

Abstract

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