Title :
Single-Polarization Elliptical-Hole Lattice Core Photonic-Bandgap Fiber
Author :
Eguchi, M. ; Tsuji, Y.
Author_Institution :
Dept. of Photonics Syst. Technol., Chitose Inst. of Sci. & Technol., Chitose, Japan
Abstract :
In photonic bandgap (PBG) fibers, light is confined by a photonic bandgap caused by a periodic structure of air holes in the cladding regions. The doubly degenerate fundamental mode in ideal PBG fiber structures becomes slightly nondegenerate in actually produced fibers, and this causes polarization instability and polarization mode dispersion. Here, to avoid these problems, we propose a novel absolutely single-polarization PBG fiber structure with an elliptical-hole lattice core. A PBG fiber with a single-polarization bandwidth of 420 nm is numerically demonstrated. Furthermore, based on the proposed fiber structure, we report another single-polarization PBG fiber that has two absolutely single-polarization bands being orthogonal to each other.
Keywords :
finite element analysis; optical fibre cladding; optical fibre polarisation; optical fibre theory; photonic band gap; photonic crystals; absolutely single-polarization bandwidth; air holes; cladding regions; doubly degenerate fundamental mode; periodic structure; photonic-bandgap fiber; single-polarization PBG fiber structure; single-polarization elliptical-hole lattice core; Indexes; Lattices; Materials; Photonic band gap; Refractive index; Vectors; Absolutely single-polarization; elliptical-hole lattice; finite-element method; honeycomb lattice; photonic bandgap fiber;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2012.2226867
