Title :
Void-Filling and Loss Reduction in PECVD Silica Waveguide Devices Using Boron–Germanium Codoped Upper Cladding
Author :
Lin, Xufeng ; Ma, Xiao ; He, Jian-Jun
Author_Institution :
State Key Lab. of Modern Opt. Instrum., Zhejiang Univ., Hangzhou, China
Abstract :
Plasma-enhanced chemical vapor deposition (PECVD) is commonly used for the deposition of silica waveguide layers. When the gaps between waveguides are small, voids are created during the deposition of the upper cladding. This letter presents a new process for filling the gaps of PECVD silica waveguides using boron-germanium codoped upper-cladding and high-temperature annealing. Using appropriate doping concentrations as determined by processing gas flow rates, the image of completely filled gap was observed by scanning electron microscopy, and the measured transmission loss of an arrayed waveguide grating triplexer is reduced by about 2 dB. By avoiding the use of toxic phosphine, the proposed method has potential advantages compared with the commonly used borophosphosilicate glass process.
Keywords :
annealing; arrayed waveguide gratings; boron; doping profiles; germanium; light transmission; multiplexing equipment; optical fabrication; optical films; optical losses; plasma CVD; scanning electron microscopy; silicon compounds; PECVD silica waveguide device; SiO2:B,Ge; arrayed waveguide grating triplexer; boron-germanium codoped upper cladding; doping concentration; gas flow rates; high-temperature annealing; plasma-enhanced chemical vapor deposition; scanning electron microscopy; toxic phosphine; transmission loss reduction; void filling; Annealing; Arrayed waveguide gratings; Chemical vapor deposition; Doping; Filling; Glass; Magnetic cores; Plasma chemistry; Plasma devices; Plasma waves; Silicon compounds; Waveguide discontinuities; Arrayed waveguide grating (AWG); integrated optics; planar lightwave circuit (PLC); silica waveguide;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2010.2064292
