Nonlinear photonic crystals in chalcogenide films

C. Grillet; D. Freeman; B. Luther-Davies; S. Madden; C. Smith; E. Magi; R. McPhedran; D. J. Moss; Michael J. Steel; B. J. Eggleton

doi:10.1117/12.651709

Nonlinear photonic crystals in chalcogenide films

C. Grillet^*, D. Freeman, B. Luther-Davies, S. Madden, C. Smith, E. Magi, R. McPhedran, D. J. Moss, Michael J. Steel, B. J. Eggleton

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

All optical switching devices based on kerr-effect, where light switches light, are enjoying renewed interest. The dream of ultra compact devices operating at very low power and integrable on a chip is entering the realm of reality thanks to the advent of photonic crystal, enabling high Q/V ratio. We show that marrying photonic crystal and a new class of highly non linear material, Chalcogenide glasses, is a very promising way to achieve an all-optical chip. We describe the fabrication techniques we have developed for manufacturing two-dimensional Chalcogenide photonic crystal. Different types of photonic crystal resonances are investigated. Coupling technique to Chalcogenide based photonic crystal waveguides and cavities via tapered nanowires is thoroughly described. We demonstrate resonant guiding in a Chalcogenide glass photonic crystal membrane using a fano probe technique. We observe strong resonances in the optical transmission spectra at normal incidence, associated with Fano coupling between free space and guided modes. We obtain good agreement with modeling results based on three-dimensional finite-difference time-domain simulations, and identify the guided modes near the centre of the first Brillouin zone responsible for the main spectral features.

Original language	English
Title of host publication	Photonics
Subtitle of host publication	Design, Technology, and Packaging II
DOIs	https://doi.org/10.1117/12.651709
Publication status	Published - 2006
Event	Photonics: Design, Technology, and Packaging II - Brisbane, Australia Duration: 12 Dec 2005 → 14 Dec 2005

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	6038
ISSN (Print)	0277-786X

Conference

Conference	Photonics: Design, Technology, and Packaging II
Country/Territory	Australia
City	Brisbane
Period	12/12/05 → 14/12/05

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10.1117/12.651709

Cite this

Grillet, C., Freeman, D., Luther-Davies, B., Madden, S., Smith, C., Magi, E., McPhedran, R., Moss, D. J., Steel, M. J., & Eggleton, B. J. (2006). Nonlinear photonic crystals in chalcogenide films. In Photonics: Design, Technology, and Packaging II Article 60380N (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 6038). https://doi.org/10.1117/12.651709

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title = "Nonlinear photonic crystals in chalcogenide films",

abstract = "All optical switching devices based on kerr-effect, where light switches light, are enjoying renewed interest. The dream of ultra compact devices operating at very low power and integrable on a chip is entering the realm of reality thanks to the advent of photonic crystal, enabling high Q/V ratio. We show that marrying photonic crystal and a new class of highly non linear material, Chalcogenide glasses, is a very promising way to achieve an all-optical chip. We describe the fabrication techniques we have developed for manufacturing two-dimensional Chalcogenide photonic crystal. Different types of photonic crystal resonances are investigated. Coupling technique to Chalcogenide based photonic crystal waveguides and cavities via tapered nanowires is thoroughly described. We demonstrate resonant guiding in a Chalcogenide glass photonic crystal membrane using a fano probe technique. We observe strong resonances in the optical transmission spectra at normal incidence, associated with Fano coupling between free space and guided modes. We obtain good agreement with modeling results based on three-dimensional finite-difference time-domain simulations, and identify the guided modes near the centre of the first Brillouin zone responsible for the main spectral features.",

author = "C. Grillet and D. Freeman and B. Luther-Davies and S. Madden and C. Smith and E. Magi and R. McPhedran and Moss, {D. J.} and Steel, {Michael J.} and Eggleton, {B. J.}",

year = "2006",

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language = "English",

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series = "Proceedings of SPIE - The International Society for Optical Engineering",

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Grillet, C, Freeman, D, Luther-Davies, B, Madden, S, Smith, C, Magi, E, McPhedran, R, Moss, DJ, Steel, MJ & Eggleton, BJ 2006, Nonlinear photonic crystals in chalcogenide films. in Photonics: Design, Technology, and Packaging II., 60380N, Proceedings of SPIE - The International Society for Optical Engineering, vol. 6038, Photonics: Design, Technology, and Packaging II, Brisbane, Australia, 12/12/05. https://doi.org/10.1117/12.651709

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T1 - Nonlinear photonic crystals in chalcogenide films

AU - Grillet, C.

AU - Freeman, D.

AU - Luther-Davies, B.

AU - Madden, S.

AU - Smith, C.

AU - Magi, E.

AU - McPhedran, R.

AU - Moss, D. J.

AU - Steel, Michael J.

AU - Eggleton, B. J.

PY - 2006

Y1 - 2006

N2 - All optical switching devices based on kerr-effect, where light switches light, are enjoying renewed interest. The dream of ultra compact devices operating at very low power and integrable on a chip is entering the realm of reality thanks to the advent of photonic crystal, enabling high Q/V ratio. We show that marrying photonic crystal and a new class of highly non linear material, Chalcogenide glasses, is a very promising way to achieve an all-optical chip. We describe the fabrication techniques we have developed for manufacturing two-dimensional Chalcogenide photonic crystal. Different types of photonic crystal resonances are investigated. Coupling technique to Chalcogenide based photonic crystal waveguides and cavities via tapered nanowires is thoroughly described. We demonstrate resonant guiding in a Chalcogenide glass photonic crystal membrane using a fano probe technique. We observe strong resonances in the optical transmission spectra at normal incidence, associated with Fano coupling between free space and guided modes. We obtain good agreement with modeling results based on three-dimensional finite-difference time-domain simulations, and identify the guided modes near the centre of the first Brillouin zone responsible for the main spectral features.

AB - All optical switching devices based on kerr-effect, where light switches light, are enjoying renewed interest. The dream of ultra compact devices operating at very low power and integrable on a chip is entering the realm of reality thanks to the advent of photonic crystal, enabling high Q/V ratio. We show that marrying photonic crystal and a new class of highly non linear material, Chalcogenide glasses, is a very promising way to achieve an all-optical chip. We describe the fabrication techniques we have developed for manufacturing two-dimensional Chalcogenide photonic crystal. Different types of photonic crystal resonances are investigated. Coupling technique to Chalcogenide based photonic crystal waveguides and cavities via tapered nanowires is thoroughly described. We demonstrate resonant guiding in a Chalcogenide glass photonic crystal membrane using a fano probe technique. We observe strong resonances in the optical transmission spectra at normal incidence, associated with Fano coupling between free space and guided modes. We obtain good agreement with modeling results based on three-dimensional finite-difference time-domain simulations, and identify the guided modes near the centre of the first Brillouin zone responsible for the main spectral features.

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DO - 10.1117/12.651709

M3 - Conference contribution

SN - 0819460699

SN - 9780819460691

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Photonics

T2 - Photonics: Design, Technology, and Packaging II

Y2 - 12 December 2005 through 14 December 2005

ER -

Nonlinear photonic crystals in chalcogenide films

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