Title :
Vacuum-ultraviolet laser-induced refractive-index change and birefringence in standard optical fibers
Author :
Chen, Kevin P. ; Herman, Peter R. ; Taylor, Rod ; Hnatovsky, Cyril
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Toronto, Ont., Canada
Abstract :
Strong photosensitivity responses with the use of above-bandgap 157-nm F2-laser radiation are reported for standard germanosilicate fiber. A large 1.3×10-3 effective index change at 1.55 μm was inferred by trimming strong and weak Bragg gratings in hydrogen-free fiber. The F2-laser fluence-processing window of <50 mJ/cm2 is much lower than with traditional ultraviolet (UV) lasers. For hydrogen-soaked fiber, highly asymmetric refractive-index profiles were noted by atomic force microscopy and microreflection microscopy, yielding a peak index change of >0.01 across a small 1-μm penetration depth at the fiber core. The index asymmetry appears to underlie the large >5×10-5 value of laser-induced birefringence.
Keywords :
Bragg gratings; atomic force microscopy; birefringence; laser materials processing; optical fibre fabrication; optical microscopy; refractive index; 157 nm; F2; F2-laser fluence-processing window; above-bandgap 157-nm F2-laser radiation; asymmetric refractive-index profiles; birefringence; effective index change; fiber core; laser-induced birefringence; microreflection microscopy; peak index change; penetration depth; standard optical fibers; vacuum-ultraviolet laser-induced refractive-index change; weak Bragg gratings; Atomic force microscopy; Birefringence; Bragg gratings; Fiber gratings; Fiber lasers; Hydrogen; Laser theory; Laser transitions; Optical fibers; Optical refraction;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2003.815647
