Title :
Miniature Hydrogen Sensor Based on Fiber Inner Cavity and Pt-doped WO3 Coating
Author :
Tian Yi Hu ; Wang, D.N. ; Min Wang ; Zhi Li ; Minghong Yang
Author_Institution :
Dept. of Electr. Eng., Hong Kong Polytech. Univ., Hong Kong, China
Abstract :
We demonstrate a miniaturized fiber device based on fiber inner air-cavity with periodical microstructures and platinum (Pt)-doped WO3 coating for hydrogen concentration sensing. The fiber inner air-cavity is formed by use of femtosecond laser micromachining together with fusion splicing technique and the line shape microstructures are inscribed by femtosecond laser beam scanning. The Pt-doped WO3 coating on the fiber surface near the cavity leads to the device sensitivity to hydrogen concentration, and the maximum wavelength shift obtained is ~2.64 nm when the hydrogen concentration is increased from 0% to 4% in volume percentage. The system is highly sensitive and miniature and exhibits a low temperature cross-sensitivity.
Keywords :
antireflection coatings; chemical sensors; fibre optic sensors; hydrogen; laser beam machining; micro-optics; micromachining; optical fibre fabrication; optical materials; platinum; splicing; tungsten compounds; H; Pt-doped WO3 coating; WO3:Pt; device sensitivity; femtosecond laser beam scanning; femtosecond laser micromachining; fiber inner air-cavity; fiber surface; fusion splicing technique; hydrogen concentration sensing; line shape microstructures; low temperature cross-sensitivity; maximum wavelength shift; miniature hydrogen sensor; miniaturized fiber device; periodical microstructures; volume percentage; Hydrogen; Microstructure; Optical fiber sensors; Optical fibers; Temperature sensors; Hydrogen sensor; femtosecond laser; fiber sensor;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2327013
