Title :
High efficiency 90/spl deg/ silica waveguide bend using an air hole photonic crystal region
Author :
Seunghyun Kim ; Nordin, G.P. ; Jianhua Jiang ; Jingbo Cai
Author_Institution :
Nano & Micro Devices Center, Univ. of Alabama, Huntsville, AL, USA
Abstract :
We propose the hybrid integration of an air hole photonic crystal (PhC) structure with a high /spl Delta/ (0.75%) single-mode silica waveguide to achieve an ultracompact high efficiency 90/spl deg/ bend for transverse-magnetic polarized light. Diffraction from the periodic boundary between the PhC and silica waveguide regions is shown to seriously degrade the optical efficiency of the bend. A microgenetic algorithm (μGA) combined with a two-dimensional finite-difference time-domain method is used to modify the PhC and its boundary layer to suppress this diffraction which in turn maximizes bend efficiency. The final optimized structure has a 99.4% bend efficiency at a wavelength of 1.55 μm and occupies an area of only 27 × 27 μm.
Keywords :
finite difference time-domain analysis; genetic algorithms; integrated optics; light diffraction; optical losses; optical waveguides; photonic crystals; silicon compounds; waveguide discontinuities; 1.55 mum; 90/spl deg/ silica waveguide bend; 99.4 percent; SiO/sub 2/; air hole photonic crystal region; bend efficiency; high-efficiency 90/spl deg/ bend; microgenetic algorithm; periodic boundary; single-mode silica waveguide; transverse-magnetic polarized light; two-dimensional finite-difference time-domain method; Optical polarization; Optical refraction; Optical variables control; Optical waveguides; Photonic band gap; Photonic crystals; Programmable control; Propagation losses; Refractive index; Silicon compounds;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2004.829758
