Confined and propagating modes of microstructured optical fibers with three-dimensional geometry variation

Adam Mock; Waylin Wing

doi:10.1109/JLT.2012.2192906

Confined and propagating modes of microstructured optical fibers with three-dimensional geometry variation

Adam Mock, Waylin Wing

Engineering & Technology, School Of

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

1 Scopus citations

Abstract

Microstructured optical fiber inline cavity designs are presented with lengths less than 60 μ m, mode volumes less than 3 (λ ₀/n) ³, and Q factors exceeding 3000. The device geometries are consistent with the fiber postprocessing capabilities of focused ion beam or femtosecond micromachining. The devices are based on introducing a longitudinally periodic hole array into a microstructured optical fiber. The micromachined fiber dispersion is calculated using the 3-D finite-different time-domain method. Bandgap frequencies, confined cavity mode frequencies, and quality factors are presented. Application of the device as a fast-response-time refractometer is explored, and sensitivities of 150 nm per refractive index unit are predicted.

Original language	English
Article number	6177205
Pages (from-to)	2134-2142
Number of pages	9
Journal	Journal of Lightwave Technology
Volume	30
Issue number	13
DOIs	https://doi.org/10.1109/JLT.2012.2192906
State	Published - 2012

Keywords

Cavities
Q factor
electromagnetic scattering by periodic structures
finite-difference time-domain method (FDTD) methods
optical fiber devices
optical fiber theory

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10.1109/JLT.2012.2192906

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title = "Confined and propagating modes of microstructured optical fibers with three-dimensional geometry variation",

abstract = "Microstructured optical fiber inline cavity designs are presented with lengths less than 60 μ m, mode volumes less than 3 (λ 0/n) 3, and Q factors exceeding 3000. The device geometries are consistent with the fiber postprocessing capabilities of focused ion beam or femtosecond micromachining. The devices are based on introducing a longitudinally periodic hole array into a microstructured optical fiber. The micromachined fiber dispersion is calculated using the 3-D finite-different time-domain method. Bandgap frequencies, confined cavity mode frequencies, and quality factors are presented. Application of the device as a fast-response-time refractometer is explored, and sensitivities of 150 nm per refractive index unit are predicted.",

keywords = "Cavities, Q factor, electromagnetic scattering by periodic structures, finite-difference time-domain method (FDTD) methods, optical fiber devices, optical fiber theory",

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AB - Microstructured optical fiber inline cavity designs are presented with lengths less than 60 μ m, mode volumes less than 3 (λ 0/n) 3, and Q factors exceeding 3000. The device geometries are consistent with the fiber postprocessing capabilities of focused ion beam or femtosecond micromachining. The devices are based on introducing a longitudinally periodic hole array into a microstructured optical fiber. The micromachined fiber dispersion is calculated using the 3-D finite-different time-domain method. Bandgap frequencies, confined cavity mode frequencies, and quality factors are presented. Application of the device as a fast-response-time refractometer is explored, and sensitivities of 150 nm per refractive index unit are predicted.

KW - Cavities

KW - Q factor

KW - electromagnetic scattering by periodic structures

KW - finite-difference time-domain method (FDTD) methods

KW - optical fiber devices

KW - optical fiber theory

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JO - Journal of Lightwave Technology

JF - Journal of Lightwave Technology

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M1 - 6177205

ER -

Confined and propagating modes of microstructured optical fibers with three-dimensional geometry variation

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