Title :
Highly compact optical waveguides with a novel pedestal geometry
Author :
Chaudhari, A.D. ; West, L.C. ; Roberts, C.W. ; Yicheng Lu
Author_Institution :
AT&T, Mount Olive, NJ, USA
fDate :
5/1/1995 12:00:00 AM
Abstract :
A structure with a large refractive index ratio between waveguide and cladding materials can be fabricated with low scattering losses by using Ge on GaAs waveguides at 10-μm wavelengths. We demonstrate two types of ultra-high confinement (UHC) dielectric waveguides using separate geometries: A ridge and a novel pedestal. Computer simulations using a time-domain finite element method and microwave-scale experiments are performed on both waveguide types. We show a waveguide thickness of 0.18 of the free-space wavelength or greater guide well-confined single-mode light for both geometries. Numerical and experimental values of the effective index agree to better than 0.5%.
Keywords :
III-V semiconductors; claddings; elemental semiconductors; finite element analysis; gallium arsenide; germanium; optical planar waveguides; refractive index; ridge waveguides; simulation; time-domain analysis; 10 mum; GaAs; GaAs waveguides; Ge; cladding materials; computer simulations; effective index; free-space wavelength; geometries; guide well-confined single-mode light; highly compact optical waveguides; large refractive index ratio; low scattering losses; microwave-scale experiments; pedestal; pedestal geometry; ridge; time-domain finite element method; ultra-high confinement dielectric waveguides; waveguide thickness; Dielectric materials; Geometrical optics; Light scattering; Optical losses; Optical materials; Optical refraction; Optical scattering; Optical variables control; Optical waveguides; Refractive index;
Journal_Title :
Photonics Technology Letters, IEEE
