Symmetry Breaking in Photonic Crystals: On-Demand Dispersion from Flatband to Dirac Cones

Hai Nguyen; Florian Dubois; Thierry Deschamps; Sebastien Cueff; Jean-Louis Leclercq; Christian Seassal; Xavier Letartre; Pierre Viktorovitch

doi:10.1103/PhysRevLett.120.066102

Symmetry Breaking in Photonic Crystals: On-Demand Dispersion from Flatband to Dirac Cones

Hai Nguyen, Florian Dubois, Thierry Deschamps, Sebastien Cueff, Jean-Louis Leclercq, Christian Seassal, Xavier Letartre, Pierre Viktorovitch

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

Abstract

We demonstrate that symmetry breaking opens a new degree of freedom to tailor energy-momentum dispersion in photonic crystals. Using a general theoretical framework in two illustrative practical structures, we show that breaking symmetry enables an on-demand tuning of the local density of states of the same photonic band from zero (Dirac cone dispersion) to infinity (flatband dispersion), as well as any constant density over an adjustable spectral range. As a proof of concept, we demonstrate experimentally the transformation of the very same photonic band from a conventional quadratic shape to a Dirac dispersion, a flatband dispersion, and a multivalley one. This transition is achieved by finely tuning the vertical symmetry breaking of the photonic structures. Our results provide an unprecedented degree of freedom for optical dispersion engineering in planar integrated photonic devices.

Original language	English
Journal	Physical review letters
Volume	120
Issue number	066102
DOIs	https://doi.org/10.1103/PhysRevLett.120.066102
Publication status	Published - 9 Feb 2018

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title = "Symmetry Breaking in Photonic Crystals: On-Demand Dispersion from Flatband to Dirac Cones",

abstract = "We demonstrate that symmetry breaking opens a new degree of freedom to tailor energy-momentum dispersion in photonic crystals. Using a general theoretical framework in two illustrative practical structures, we show that breaking symmetry enables an on-demand tuning of the local density of states of the same photonic band from zero (Dirac cone dispersion) to infinity (flatband dispersion), as well as any constant density over an adjustable spectral range. As a proof of concept, we demonstrate experimentally the transformation of the very same photonic band from a conventional quadratic shape to a Dirac dispersion, a flatband dispersion, and a multivalley one. This transition is achieved by finely tuning the vertical symmetry breaking of the photonic structures. Our results provide an unprecedented degree of freedom for optical dispersion engineering in planar integrated photonic devices.",

author = "Hai Nguyen and Florian Dubois and Thierry Deschamps and Sebastien Cueff and Jean-Louis Leclercq and Christian Seassal and Xavier Letartre and Pierre Viktorovitch",

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AU - Nguyen, Hai

AU - Dubois, Florian

AU - Deschamps, Thierry

AU - Cueff, Sebastien

AU - Leclercq, Jean-Louis

AU - Seassal, Christian

AU - Letartre, Xavier

AU - Viktorovitch, Pierre

PY - 2018/2/9

Y1 - 2018/2/9

N2 - We demonstrate that symmetry breaking opens a new degree of freedom to tailor energy-momentum dispersion in photonic crystals. Using a general theoretical framework in two illustrative practical structures, we show that breaking symmetry enables an on-demand tuning of the local density of states of the same photonic band from zero (Dirac cone dispersion) to infinity (flatband dispersion), as well as any constant density over an adjustable spectral range. As a proof of concept, we demonstrate experimentally the transformation of the very same photonic band from a conventional quadratic shape to a Dirac dispersion, a flatband dispersion, and a multivalley one. This transition is achieved by finely tuning the vertical symmetry breaking of the photonic structures. Our results provide an unprecedented degree of freedom for optical dispersion engineering in planar integrated photonic devices.

AB - We demonstrate that symmetry breaking opens a new degree of freedom to tailor energy-momentum dispersion in photonic crystals. Using a general theoretical framework in two illustrative practical structures, we show that breaking symmetry enables an on-demand tuning of the local density of states of the same photonic band from zero (Dirac cone dispersion) to infinity (flatband dispersion), as well as any constant density over an adjustable spectral range. As a proof of concept, we demonstrate experimentally the transformation of the very same photonic band from a conventional quadratic shape to a Dirac dispersion, a flatband dispersion, and a multivalley one. This transition is achieved by finely tuning the vertical symmetry breaking of the photonic structures. Our results provide an unprecedented degree of freedom for optical dispersion engineering in planar integrated photonic devices.

U2 - 10.1103/PhysRevLett.120.066102

DO - 10.1103/PhysRevLett.120.066102

M3 - Article

VL - 120

JO - Physical review letters

JF - Physical review letters

IS - 066102

ER -

Symmetry Breaking in Photonic Crystals: On-Demand Dispersion from Flatband to Dirac Cones

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