Title :
A Novel Polarization Splitter Based on Dual-Core Photonic Crystal Fiber With a Liquid Crystal Modulation Core
Author :
Chen, H.L. ; Li, S.G. ; Fan, Z.K. ; An, G.W. ; Li, Jenny S. ; Han, Yi
Author_Institution :
Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, China
Abstract :
A novel polarization splitter based on dual-core silica glass photonic crystal fiber with a liquid crystal modulation core is studied by the finite-element method. The mode birefringence is enlarged greatly with the infilling of nematic liquid crystal of E7. The simulation results demonstrate that the polarization splitter has an ultrabroad bandwidth of 250 nm, covering the E S C L optical communication bands, with the extinction ratio better than -20 dB. The separate length is 0.175 mm, and the extinction ratio is -80.7 dB at the communication wavelength of 1550 nm. The polarization splitter exhibits satisfactory splitter performance as the fabrication deviation reaches to 1%. The extinction ratio maintains better than -20 dB, at the C L optical communication bands, as the temperature increases from 15 °C to 50 °C.
Keywords :
birefringence; finite element analysis; holey fibres; liquid crystals; optical beam splitters; optical communication equipment; optical fibre communication; optical fibre fabrication; optical fibre polarisation; optical modulation; optical polarisers; photonic crystals; E S C L optical communication bands; E7 nematic liquid crystal; dual-core photonic crystal fiber; extinction ratio; finite-element method; liquid crystal modulation core; mode birefringence; polarization splitter; temperature 15 degC; temperature 50 degC; wavelength 1550 nm; Bandwidth; Couplings; Erbium; Extinction ratio; Fabrication; Modulation; Photonic crystal fibers; Beam splitters; Liquid crystal; Photonic crystal fiber;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2014.2337874
