Orbital Edge States in a Photonic Honeycomb Lattice

M. Milićević; T. Ozawa; G. Montambaux; I. Carusotto; E. Galopin; A. Lemaître; L. Le Gratiet; I. Sagnes; J. Bloch; A. Amo

doi:10.1103/PhysRevLett.118.107403

Orbital Edge States in a Photonic Honeycomb Lattice

M. Milićević
, T. Ozawa
, G. Montambaux
, I. Carusotto
, E. Galopin
, A. Lemaître
, L. Le Gratiet
, I. Sagnes
, J. Bloch
, A. Amo

École Polytechnique

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

Résumé

We experimentally reveal the emergence of edge states in a photonic lattice with orbital bands. We use a two-dimensional honeycomb lattice of coupled micropillars whose bulk spectrum shows four gapless bands arising from the coupling of p-like photonic orbitals. We observe zero-energy edge states whose topological origin is similar to that of conventional edge states in graphene. Additionally, we report novel dispersive edge states in zigzag and armchair edges. The observations are reproduced by tight-binding and analytical calculations, which we extend to bearded edges. Our work shows the potentiality of coupled micropillars in elucidating some of the electronic properties of emergent two-dimensional materials with orbital bands.

langue originale	Anglais
Numéro d'article	107403
journal	Physical Review Letters
Volume	118
Numéro de publication	10
Les DOIs	https://doi.org/10.1103/PhysRevLett.118.107403
état	Publié - 8 mars 2017

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10.1103/PhysRevLett.118.107403

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title = "Orbital Edge States in a Photonic Honeycomb Lattice",

abstract = "We experimentally reveal the emergence of edge states in a photonic lattice with orbital bands. We use a two-dimensional honeycomb lattice of coupled micropillars whose bulk spectrum shows four gapless bands arising from the coupling of p-like photonic orbitals. We observe zero-energy edge states whose topological origin is similar to that of conventional edge states in graphene. Additionally, we report novel dispersive edge states in zigzag and armchair edges. The observations are reproduced by tight-binding and analytical calculations, which we extend to bearded edges. Our work shows the potentiality of coupled micropillars in elucidating some of the electronic properties of emergent two-dimensional materials with orbital bands.",

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AU - Milićević, M.

AU - Ozawa, T.

AU - Montambaux, G.

AU - Carusotto, I.

AU - Galopin, E.

AU - Lemaître, A.

AU - Le Gratiet, L.

AU - Sagnes, I.

AU - Bloch, J.

AU - Amo, A.

PY - 2017/3/8

Y1 - 2017/3/8

N2 - We experimentally reveal the emergence of edge states in a photonic lattice with orbital bands. We use a two-dimensional honeycomb lattice of coupled micropillars whose bulk spectrum shows four gapless bands arising from the coupling of p-like photonic orbitals. We observe zero-energy edge states whose topological origin is similar to that of conventional edge states in graphene. Additionally, we report novel dispersive edge states in zigzag and armchair edges. The observations are reproduced by tight-binding and analytical calculations, which we extend to bearded edges. Our work shows the potentiality of coupled micropillars in elucidating some of the electronic properties of emergent two-dimensional materials with orbital bands.

AB - We experimentally reveal the emergence of edge states in a photonic lattice with orbital bands. We use a two-dimensional honeycomb lattice of coupled micropillars whose bulk spectrum shows four gapless bands arising from the coupling of p-like photonic orbitals. We observe zero-energy edge states whose topological origin is similar to that of conventional edge states in graphene. Additionally, we report novel dispersive edge states in zigzag and armchair edges. The observations are reproduced by tight-binding and analytical calculations, which we extend to bearded edges. Our work shows the potentiality of coupled micropillars in elucidating some of the electronic properties of emergent two-dimensional materials with orbital bands.

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Orbital Edge States in a Photonic Honeycomb Lattice

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