Title :
Fluidic Sensors Based on Photonic Crystal Fiber Gratings: Impact of the Ambient Temperature
Author :
Florous, Nikolaos John ; Saitoh, Kunimasa ; Varsheney, Shailendra K. ; Koshiba, Masanori
Author_Institution :
Div. of Media & Network Technol., Hokkaido Univ., Sapporo
Abstract :
The spectral and thermooptical responses of photonic crystal fiber gratings (PCFGs) infiltrated with gaseous solutions, are investigated theoretically using an accurate semivectorial modal solver combined with exact equations for the reflection response of fiber Bragg gratings. We demonstrate numerically perhaps for the first time, that by an appropriate selection of the design parameters, it is possible to obtain compact sensing platforms based on the shift of the calculated reflectance spectra of the PCFG. Thus, our investigation adds evidence to the potential use of PCFGs as gas/liquid sensors. In addition, we show through a thermooptical sensitivity analysis that this type of sensors can easily meet the requirements for channel allocation in wavelength-division-multiplexing systems with relatively low temperature sensitivity
Keywords :
Bragg gratings; channel allocation; fibre optic sensors; gas sensors; light reflection; microfluidics; optical communication equipment; optical fibres; photonic crystals; reflectivity; thermo-optical effects; wavelength division multiplexing; 293 to 298 K; ambient temperature; channel allocation; compact sensing platforms; fiber Bragg gratings; fluidic sensors; gas sensors; gaseous solutions; liquid sensors; photonic crystal fiber gratings; reflectance spectra; reflection response; semivectorial modal solver; spectral response; spectral shift; temperature sensitivity; thermooptical response; thermooptical sensitivity analysis; wavelength-division-multiplexing; Bragg gratings; Equations; Fiber gratings; Gas detectors; Optoelectronic and photonic sensors; Photonic crystal fibers; Reflection; Reflectivity; Sensitivity analysis; Temperature sensors; Bragg gratings; gas sensors; photonic crystal fiber (PCF); sensitivity analysis; temperature-dependent Sellmeier equations; virtual boundary method;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.884275
