Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips

Roman Bruck; Changxu Liu; Otto L Muskens; Andrea Fratalocchi; Andrea Di Falco

doi:10.1002/lpor.201600086

Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips

Roman Bruck, Changxu Liu, Otto L Muskens, Andrea Fratalocchi, Andrea Di Falco

School of Physics and Astronomy

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

Abstract

The interaction of light with nanostructured materials provides exciting new opportunities for investigating classical wave analogies of quantum phenomena. A topic of particular interest forms the interplay between wave physics and chaos in systems where a small perturbation can drive the behavior from the classical to chaotic regime. Here, we report an all-optical laser-driven
transition from order to chaos in integrated chips on a silicon photonics platform. A square photonic crystal microcavity at telecom wavelengths is tuned from an ordered into a chaotic regime through a perturbation induced by ultrafast laser pulses in the ultraviolet range. The chaotic dynamics of weak probe pulses in the near infrared is characterized for different pump-probe delay times and at various positions in the cavity, with high spatial accuracy. Our experimental analysis, confirmed by numerical modelling based on random matrices, demonstrates that nonlinear optics can be used to control reversibly the chaotic behavior of light in optical resonators.

Original language	English
Pages (from-to)	688-695
Journal	Laser & Photonics Reviews
Volume	10
Issue number	4
Early online date	8 Jun 2016
DOIs	https://doi.org/10.1002/lpor.201600086
Publication status	Published - Jul 2016

Keywords

Photonic crystals
Instabilities and chaos
Optical resonators
Ultrafast processes in condensed matter
Statistical optics

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10.1002/lpor.201600086

Bruck_et_al_rev
© 2016, WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. This work is made available online in accordance with the publisher’s policies. This is the author created, accepted version manuscript following peer review and may differ slightly from the final published version. The final published version of this work is available at onlinelibrary.wiley.com / https://dx.doi.org/10.1002/lpor.201600086
Accepted author manuscript, 3.76 MB

Equipment Account: Characterisation and Manipulation of Advanced Functional Materials and their Interfaces at the Nanoscale
Samuel, I. D. W. (PI)
EPSRC
1/10/13 → 30/09/23
Project: Standard
Upgrade Small Equipment Base: Small items of research equipment at the University of St Andrews. Supporting a new generation of physical sciences research
Woollins, J. D. (PI)
EPSRC
1/11/12 → 31/03/13
Project: Standard

Data underpinning - Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips
Bruck, R. (Creator), Liu, C. (Creator), Muskens, O. L. (Creator), Fratalocchi, A. (Creator) & Di Falco, A. (Creator), University of St Andrews, 2016
DOI: 10.17630/5857f38f-ee2b-494a-8e83-7529f1e6cebf
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Cite this

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title = "Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips",

abstract = "The interaction of light with nanostructured materials provides exciting new opportunities for investigating classical wave analogies of quantum phenomena. A topic of particular interest forms the interplay between wave physics and chaos in systems where a small perturbation can drive the behavior from the classical to chaotic regime. Here, we report an all-optical laser-driventransition from order to chaos in integrated chips on a silicon photonics platform. A square photonic crystal microcavity at telecom wavelengths is tuned from an ordered into a chaotic regime through a perturbation induced by ultrafast laser pulses in the ultraviolet range. The chaotic dynamics of weak probe pulses in the near infrared is characterized for different pump-probe delay times and at various positions in the cavity, with high spatial accuracy. Our experimental analysis, confirmed by numerical modelling based on random matrices, demonstrates that nonlinear optics can be used to control reversibly the chaotic behavior of light in optical resonators.",

keywords = "Photonic crystals, Instabilities and chaos, Optical resonators, Ultrafast processes in condensed matter, Statistical optics",

author = "Roman Bruck and Changxu Liu and Muskens, {Otto L} and Andrea Fratalocchi and {Di Falco}, Andrea",

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AU - Bruck, Roman

AU - Liu, Changxu

AU - Muskens, Otto L

AU - Fratalocchi, Andrea

AU - Di Falco, Andrea

N1 - ADF acknowledges support from EPSRC (EP/L017008/1).

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KW - Instabilities and chaos

KW - Optical resonators

KW - Ultrafast processes in condensed matter

KW - Statistical optics

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Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips

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Equipment Account: Characterisation and Manipulation of Advanced Functional Materials and their Interfaces at the Nanoscale

Upgrade Small Equipment Base: Small items of research equipment at the University of St Andrews. Supporting a new generation of physical sciences research

Datasets

Data underpinning - Ultrafast all-optical order-to-chaos transition in silicon photonic crystal chips

Cite this