Two-dimensional optical chimera states in an array of coupled waveguide resonators

M. G. Clerc; S. Coulibaly; M. A. Ferré; M. Tlidi

doi:10.1063/1.5133836

Two-dimensional optical chimera states in an array of coupled waveguide resonators

M. G. Clerc
, S. Coulibaly
, M. A. Ferré
, M. Tlidi

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

15 Scopus citations

Abstract

Two-dimensional arrays of coupled waveguides or coupled microcavities allow us to confine and manipulate light. Based on a paradigmatic envelope equation, we show that these devices, subject to a coherent optical injection, support coexistence between a coherent and incoherent emission. In this regime, we show that two-dimensional chimera states can be generated. Depending on initial conditions, the system exhibits a family of two-dimensional chimera states and interaction between them. We characterize these two-dimensional structures by computing their Lyapunov spectrum and Yorke-Kaplan dimension. Finally, we show that two-dimensional chimera states are of spatiotemporal chaotic nature.

Original language	English
Article number	043107
Journal	Chaos
Volume	30
Issue number	4
DOIs	https://doi.org/10.1063/1.5133836
State	Published - 1 Apr 2020
Externally published	Yes

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Mathematical Physics
General Physics and Astronomy
Applied Mathematics

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10.1063/1.5133836

Cite this

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title = "Two-dimensional optical chimera states in an array of coupled waveguide resonators",

abstract = "Two-dimensional arrays of coupled waveguides or coupled microcavities allow us to confine and manipulate light. Based on a paradigmatic envelope equation, we show that these devices, subject to a coherent optical injection, support coexistence between a coherent and incoherent emission. In this regime, we show that two-dimensional chimera states can be generated. Depending on initial conditions, the system exhibits a family of two-dimensional chimera states and interaction between them. We characterize these two-dimensional structures by computing their Lyapunov spectrum and Yorke-Kaplan dimension. Finally, we show that two-dimensional chimera states are of spatiotemporal chaotic nature.",

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AU - Clerc, M. G.

AU - Coulibaly, S.

AU - Ferré, M. A.

AU - Tlidi, M.

PY - 2020/4/1

Y1 - 2020/4/1

N2 - Two-dimensional arrays of coupled waveguides or coupled microcavities allow us to confine and manipulate light. Based on a paradigmatic envelope equation, we show that these devices, subject to a coherent optical injection, support coexistence between a coherent and incoherent emission. In this regime, we show that two-dimensional chimera states can be generated. Depending on initial conditions, the system exhibits a family of two-dimensional chimera states and interaction between them. We characterize these two-dimensional structures by computing their Lyapunov spectrum and Yorke-Kaplan dimension. Finally, we show that two-dimensional chimera states are of spatiotemporal chaotic nature.

AB - Two-dimensional arrays of coupled waveguides or coupled microcavities allow us to confine and manipulate light. Based on a paradigmatic envelope equation, we show that these devices, subject to a coherent optical injection, support coexistence between a coherent and incoherent emission. In this regime, we show that two-dimensional chimera states can be generated. Depending on initial conditions, the system exhibits a family of two-dimensional chimera states and interaction between them. We characterize these two-dimensional structures by computing their Lyapunov spectrum and Yorke-Kaplan dimension. Finally, we show that two-dimensional chimera states are of spatiotemporal chaotic nature.

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VL - 30

JO - Chaos

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ER -

Two-dimensional optical chimera states in an array of coupled waveguide resonators

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ASJC Scopus subject areas

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