Direct observation of Dirac cones and a flatband in a honeycomb lattice for polaritons

T. Jacqmin; I. Carusotto; I. Sagnes; M. Abbarchi; D. D. Solnyshkov; G. Malpuech; E. Galopin; A. Lemaître; J. Bloch; A. Amo

doi:10.1103/PhysRevLett.112.116402

Direct observation of Dirac cones and a flatband in a honeycomb lattice for polaritons

T. Jacqmin
, I. Carusotto
, I. Sagnes
, M. Abbarchi
, D. D. Solnyshkov
, G. Malpuech
, E. Galopin
, A. Lemaître
, J. Bloch
, A. Amo

École Polytechnique

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

Abstract

Two-dimensional lattices of coupled micropillars etched in a planar semiconductor microcavity offer a workbench to engineer the band structure of polaritons. We report experimental studies of honeycomb lattices where the polariton low-energy dispersion is analogous to that of electrons in graphene. Using energy-resolved photoluminescence, we directly observe Dirac cones, around which the dynamics of polaritons is described by the Dirac equation for massless particles. At higher energies, we observe p orbital bands, one of them with the nondispersive character of a flatband. The realization of this structure which holds massless, massive, and infinitely massive particles opens the route towards studies of the interplay of dispersion, interactions, and frustration in a novel and controlled environment.

Original language	English
Article number	116402
Journal	Physical Review Letters
Volume	112
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.112.116402
Publication status	Published - 18 Mar 2014

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10.1103/PhysRevLett.112.116402

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abstract = "Two-dimensional lattices of coupled micropillars etched in a planar semiconductor microcavity offer a workbench to engineer the band structure of polaritons. We report experimental studies of honeycomb lattices where the polariton low-energy dispersion is analogous to that of electrons in graphene. Using energy-resolved photoluminescence, we directly observe Dirac cones, around which the dynamics of polaritons is described by the Dirac equation for massless particles. At higher energies, we observe p orbital bands, one of them with the nondispersive character of a flatband. The realization of this structure which holds massless, massive, and infinitely massive particles opens the route towards studies of the interplay of dispersion, interactions, and frustration in a novel and controlled environment.",

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AU - Jacqmin, T.

AU - Carusotto, I.

AU - Sagnes, I.

AU - Abbarchi, M.

AU - Solnyshkov, D. D.

AU - Malpuech, G.

AU - Galopin, E.

AU - Lemaître, A.

AU - Bloch, J.

AU - Amo, A.

PY - 2014/3/18

Y1 - 2014/3/18

N2 - Two-dimensional lattices of coupled micropillars etched in a planar semiconductor microcavity offer a workbench to engineer the band structure of polaritons. We report experimental studies of honeycomb lattices where the polariton low-energy dispersion is analogous to that of electrons in graphene. Using energy-resolved photoluminescence, we directly observe Dirac cones, around which the dynamics of polaritons is described by the Dirac equation for massless particles. At higher energies, we observe p orbital bands, one of them with the nondispersive character of a flatband. The realization of this structure which holds massless, massive, and infinitely massive particles opens the route towards studies of the interplay of dispersion, interactions, and frustration in a novel and controlled environment.

AB - Two-dimensional lattices of coupled micropillars etched in a planar semiconductor microcavity offer a workbench to engineer the band structure of polaritons. We report experimental studies of honeycomb lattices where the polariton low-energy dispersion is analogous to that of electrons in graphene. Using energy-resolved photoluminescence, we directly observe Dirac cones, around which the dynamics of polaritons is described by the Dirac equation for massless particles. At higher energies, we observe p orbital bands, one of them with the nondispersive character of a flatband. The realization of this structure which holds massless, massive, and infinitely massive particles opens the route towards studies of the interplay of dispersion, interactions, and frustration in a novel and controlled environment.

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Direct observation of Dirac cones and a flatband in a honeycomb lattice for polaritons

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