Title :
Waveguide-based photonic microstructures in semiconductors
Author :
Krauss, Thomas E. ; Brand, Stuart ; De La Rue, Richard M.
Author_Institution :
Dept. of Electron. & Electr. Eng., Glasgow Univ., UK
Abstract :
The promising concepts of photonic microstructures are finally beginning to enter the realm of optical wavelengths: following a number of years of speculative theoretical work and experiments in the microwave regime, we present the first demonstration of strong photonic bandgap effects in semiconductors at optical wavelengths below 1 μm. We have observed both short and long wavelength band-edges in a 2-D waveguide structure and microcavity effects in a 1-D waveguide structure. Typically, the 2-D lattices consist of a hexagonal close packed (HCP) array of holes etched into the semiconductor (“honeycomb structure”) with a period of 190 nm, a hole diameter of 100-120 nm and an etch depth of 0.5-0.6 μm. The 3d order 1-D microcavity structure has a period of 400-500 nm and incorporates a λ/4 phase shift. From the spectral response, we can assign a Q-value of approximately 2500 to this λ/4 microcavity. To our knowledge, this is the highest quality factor of all waveguide-based photonic microcavities either proposed or demonstrated to date
Keywords :
Q-factor; λ/4 phase shift; 0.5 to 0.6 mum; 1 mum; 100 to 120 nm; 1D waveguide structure; 2D waveguide structure; Q-value; etch depth; hexagonal close packed array; hole diameter; long wavelength band-edges; microcavity effects; microcavity structure; microwave regime; optical wavelengths; photonic bandgap effects; quality factor; semiconductor honeycomb structure; semiconductors; short wavelength band-edges; spectral response; waveguide-based photonic microcavities; waveguide-based photonic microstructures;
Conference_Titel :
Semiconductor Optical Microcavity Devices and Photonic Bandgaps (Digest No. 1996/267), IEE Colloquium on
Conference_Location :
London
DOI :
10.1049/ic:19961417
