Emulating the local Kuramoto model with an injection-locked photonic crystal laser array

Abstract The Kuramoto model is a mathematical model for describing the collective synchronization phenomena of coupled oscillators. We theoretically demonstrate that an array of coupled photonic crystal lasers emulates the Kuramoto model with non-delayed nearest-neighbor coupling (the local Kuramoto...

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Main Authors: Naotomo Takemura, Kenta Takata, Masato Takiguchi, Masaya Notomi
Format: Article
Language:English
Published: Nature Publishing Group 2021-04-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-86982-w
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spelling doaj-b48ab433289146f5b9bc52aab0d263682021-04-25T11:34:32ZengNature Publishing GroupScientific Reports2045-23222021-04-0111111110.1038/s41598-021-86982-wEmulating the local Kuramoto model with an injection-locked photonic crystal laser arrayNaotomo Takemura0Kenta Takata1Masato Takiguchi2Masaya Notomi3Nanophotonics Center, NTT Corp.Nanophotonics Center, NTT Corp.Nanophotonics Center, NTT Corp.Nanophotonics Center, NTT Corp.Abstract The Kuramoto model is a mathematical model for describing the collective synchronization phenomena of coupled oscillators. We theoretically demonstrate that an array of coupled photonic crystal lasers emulates the Kuramoto model with non-delayed nearest-neighbor coupling (the local Kuramoto model). Our novel strategy employs indirect coupling between lasers via additional cold cavities. By installing cold cavities between laser cavities, we avoid the strong coupling of lasers and realize ideal mutual injection-locking with effective non-delayed dissipative coupling. First, after discussing the limit cycle interpretation of laser oscillation, we demonstrate the synchronization of two indirectly coupled lasers by numerically simulating coupled-mode equations. Second, by performing a phase reduction analysis, we show that laser dynamics in the proposed device can be mapped to the local Kuramoto model. Finally, we briefly demonstrate that a chain of indirectly coupled photonic crystal lasers actually emulates the one-dimensional local Kuramoto chain. We also argue that our proposed structure, which consists of periodically aligned cold cavities and laser cavities, will best be realized by using state-of-the-art buried multiple quantum well photonic crystals.https://doi.org/10.1038/s41598-021-86982-w
collection DOAJ
language English
format Article
sources DOAJ
author Naotomo Takemura
Kenta Takata
Masato Takiguchi
Masaya Notomi
spellingShingle Naotomo Takemura
Kenta Takata
Masato Takiguchi
Masaya Notomi
Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
Scientific Reports
author_facet Naotomo Takemura
Kenta Takata
Masato Takiguchi
Masaya Notomi
author_sort Naotomo Takemura
title Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
title_short Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
title_full Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
title_fullStr Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
title_full_unstemmed Emulating the local Kuramoto model with an injection-locked photonic crystal laser array
title_sort emulating the local kuramoto model with an injection-locked photonic crystal laser array
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-04-01
description Abstract The Kuramoto model is a mathematical model for describing the collective synchronization phenomena of coupled oscillators. We theoretically demonstrate that an array of coupled photonic crystal lasers emulates the Kuramoto model with non-delayed nearest-neighbor coupling (the local Kuramoto model). Our novel strategy employs indirect coupling between lasers via additional cold cavities. By installing cold cavities between laser cavities, we avoid the strong coupling of lasers and realize ideal mutual injection-locking with effective non-delayed dissipative coupling. First, after discussing the limit cycle interpretation of laser oscillation, we demonstrate the synchronization of two indirectly coupled lasers by numerically simulating coupled-mode equations. Second, by performing a phase reduction analysis, we show that laser dynamics in the proposed device can be mapped to the local Kuramoto model. Finally, we briefly demonstrate that a chain of indirectly coupled photonic crystal lasers actually emulates the one-dimensional local Kuramoto chain. We also argue that our proposed structure, which consists of periodically aligned cold cavities and laser cavities, will best be realized by using state-of-the-art buried multiple quantum well photonic crystals.
url https://doi.org/10.1038/s41598-021-86982-w
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AT kentatakata emulatingthelocalkuramotomodelwithaninjectionlockedphotoniccrystallaserarray
AT masatotakiguchi emulatingthelocalkuramotomodelwithaninjectionlockedphotoniccrystallaserarray
AT masayanotomi emulatingthelocalkuramotomodelwithaninjectionlockedphotoniccrystallaserarray
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