Title :
Tunable Photonic Crystal Fiber Couplers With a Thermo-Responsive Liquid Crystal Resonator
Author :
Saitoh, Kunimasa ; Florous, Nikolaos J. ; Varshney, Shailendra K. ; Koshiba, Masanori
Author_Institution :
Hokkaido Univ., Sapporo
fDate :
3/15/2008 12:00:00 AM
Abstract :
We theoretically address the thermo-optical response of multicore photonic crystal fiber (PCF) couplers infiltrated with nematic liquid crystals (LCs). The proposed PCF coupler consists of two identical cores separated by a third one which acts as a liquid crystal resonator. With an appropriate choice of the design parameters associated with the liquid crystal core, phase matching at a single wavelength can be achieved, thus enabling thermo-tunable narrow-band resonant directional coupling between the input and the output cores. The verification of the proposed coupler design is ensured through an accurate PCF analysis based on finite element and beam propagation methods. The enhanced thermo-optical properties of LC-based PCF couplers are highly attractive for photo-thermal sensing applications.
Keywords :
fibre optic sensors; finite element analysis; integrated optics; liquid crystal devices; nematic liquid crystals; optical design techniques; optical directional couplers; optical fibre couplers; optical phase matching; optical resonators; photonic crystals; photothermal effects; temperature sensors; thermo-optical devices; beam propagation method; coupler design; finite element method; liquid crystal resonator; narrow-band resonant coupling; nematic liquid crystals; phase matching; photonic crystal fiber couplers; photothermal sensing; thermooptical response; thermoresponsive resonator; thermotunable directional coupling; tunable fiber couplers; Couplers; Finite element methods; Frequency conversion; Liquid crystals; Multicore processing; Narrowband; Photonic crystal fibers; Photonic crystals; Resonance; Thermooptical devices; Bandpass filter; finite-element method (FEM); holey fiber; liquid crystal (LC); microstructured optical fiber; photonic crystal fiber (PCF); resonant coupling; thermal sensors;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2007.915276
