Franco, Marcos A.R.Patrício, Paulo S. [UNESP]Pitarello, Tânia R.2014-05-272014-05-272010-12-01Proceedings of SPIE - The International Society for Optical Engineering, v. 7839.0277-786Xhttp://hdl.handle.net/11449/72061We address the bandgap effect and the thermo-optical response of high-index liquid crystal (LC) infiltrated in photonic crystal fibers (PCF) and in hybrid photonic crystal fibers (HPCF). The PCF and HPCF consist of solid-core microstructured optical fibers with hexagonal lattice of air-holes or holes filled with LC. The HPCF is built from the PCF design by changing its cladding microstructure only in a horizontal central line by including large holes filled with high-index material. The HPCF supports propagating optical modes by two physical effects: the modified total internal reflection (mTIR) and the photonic bandgap (PBG). Nevertheless conventional PCF propagates light by the mTIR effect if holes are filled with low refractive index material or by the bandgap effect if the microstructure of holes is filled with high refractive-index material. The presence of a line of holes with high-index LC determines that low-loss optical propagation only occurs on the bandgap condition. The considered nematic liquid crystal E7 is an anisotropic uniaxial media with large thermo-optic coefficient; consequently temperature changes cause remarkable shifts in the transmission spectrums allowing thermal tunability of the bandgaps. Photonic bandgap guidance and thermally induced changes in the transmission spectrum were numerically investigated by using a computational program based on the beam propagation method. © 2010 SPIE.engFiber opticsLiquid crystalMicrostructured optical fibersPhotonic bandgapPhotonic crystal fibersAir holesBand gap effectsBand gapsComputational programHexagonal latticeHigh Index materialsHigh-indexHybrid photonic crystalsIndex materialLow lossLow-refractive-index materialsMicro-structured optical fibersNematic liquidsOptical modesOptical propagationPhysical effectsTemperature changesThermally inducedThermo-optic coefficientsThermo-opticalTotal internal reflectionsTransmission spectrumsTunabilitiesUniaxial mediaAnisotropic mediaCrystal whiskersEnergy gapFibersLiquid crystalsLiquidsMetal claddingMicrostructureNematic liquid crystalsOptical fibersOptical waveguidesPhotonic bandgap fibersRefractive indexSpontaneous emissionPhotonic crystalsTrabalho apresentado em evento10.1117/12.868246Acesso aberto2-s2.0-79953123514