Edge States for Tight-Binding Operators with Soft Walls

Camilo Gómez Araya; David Gontier; Hanne Van Den Bosch

doi:10.1007/s00220-025-05326-1

Edge States for Tight-Binding Operators with Soft Walls

Camilo Gómez Araya
, David Gontier
, Hanne Van Den Bosch

Université Paris Dauphine
Facultad de Ciencias Físicas y Matemáticas de la Universidad de Chile

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We study one- and two-dimensional periodic tight-binding models in the presence of a potential that grows to infinity in one direction, hence preventing the particles to escape in this direction (the soft wall). We prove that a spectral flow appears in these edge models, as the wall is shifted with respect to the lattice. We identity this flow with the number of Bloch bands. This provides a lower bound for the number of edge states appearing in such models. For the two-dimensional case, we compute the spectral flow for edges that have any rational orientation with respect to the lattice. The results are illustrated by applying them to the one-dimensional SSH chain and the Wallace model for graphene.

langue originale	Anglais
Numéro d'article	160
journal	Communications in Mathematical Physics
Volume	406
Numéro de publication	7
Les DOIs	https://doi.org/10.1007/s00220-025-05326-1
état	Publié - 1 juil. 2025

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abstract = "We study one- and two-dimensional periodic tight-binding models in the presence of a potential that grows to infinity in one direction, hence preventing the particles to escape in this direction (the soft wall). We prove that a spectral flow appears in these edge models, as the wall is shifted with respect to the lattice. We identity this flow with the number of Bloch bands. This provides a lower bound for the number of edge states appearing in such models. For the two-dimensional case, we compute the spectral flow for edges that have any rational orientation with respect to the lattice. The results are illustrated by applying them to the one-dimensional SSH chain and the Wallace model for graphene.",

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AU - Gómez Araya, Camilo

AU - Gontier, David

AU - Van Den Bosch, Hanne

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2025.

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N2 - We study one- and two-dimensional periodic tight-binding models in the presence of a potential that grows to infinity in one direction, hence preventing the particles to escape in this direction (the soft wall). We prove that a spectral flow appears in these edge models, as the wall is shifted with respect to the lattice. We identity this flow with the number of Bloch bands. This provides a lower bound for the number of edge states appearing in such models. For the two-dimensional case, we compute the spectral flow for edges that have any rational orientation with respect to the lattice. The results are illustrated by applying them to the one-dimensional SSH chain and the Wallace model for graphene.

AB - We study one- and two-dimensional periodic tight-binding models in the presence of a potential that grows to infinity in one direction, hence preventing the particles to escape in this direction (the soft wall). We prove that a spectral flow appears in these edge models, as the wall is shifted with respect to the lattice. We identity this flow with the number of Bloch bands. This provides a lower bound for the number of edge states appearing in such models. For the two-dimensional case, we compute the spectral flow for edges that have any rational orientation with respect to the lattice. The results are illustrated by applying them to the one-dimensional SSH chain and the Wallace model for graphene.

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Edge States for Tight-Binding Operators with Soft Walls

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