مرکز منطقه ای اطلاع رساني علوم و فناوري - Confined and Propagating Modes of Microstructured Optical Fibers With Three-Dimensional Geometry Variation

DocumentCode :

1481399

Title :

Confined and Propagating Modes of Microstructured Optical Fibers With Three-Dimensional Geometry Variation

Author :

Mock, Adam ; Wing, Waylin

Author_Institution :

Sch. of Eng. & Technol., Central Michigan Univ., Mount Pleasant, MI, USA

Volume :

Issue :

fYear :

2012

fDate :

7/1/2012 12:00:00 AM

Firstpage :

2134

Lastpage :

2142

Abstract :

Microstructured optical fiber inline cavity designs are presented with lengths less than 60 μm, mode volumes less than 3 (λ₀/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 :

Q-factor; finite difference time-domain analysis; holey fibres; light propagation; micromachining; optical fibre dispersion; 3D finite-different time-domain method; Q factor; bandgap frequencies; confined cavity mode frequencies; device geometries; fast-response-time refractometer; femtosecond micromachining; fiber postprocessing capabilities; focused ion beam; longitudinally periodic hole array; micromachined fiber dispersion; microstructured optical fibers; mode volumes; propagating mode; quality factors; refractive index unit; three-dimensional geometry variation; Cavity resonators; Dispersion; Nonlinear optics; Optical refraction; Optical variables control; Photonic band gap; Ultrafast optics; $Q$ factor; Cavities; electromagnetic scattering by periodic structures; finite-difference time-domain method (FDTD) methods; optical fiber devices; optical fiber theory;

fLanguage :

English

Journal_Title :

Lightwave Technology, Journal of

Publisher :

ieee

ISSN :

0733-8724

Type :

jour

DOI :

10.1109/JLT.2012.2192906

Filename :

6177205

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=1481399