Title :
Photonic Band Gap Materials: Engineering Light-Matter Interactions
Author_Institution :
Univ. of Toronto, Toronto
fDate :
Aug. 12 2007-July 16 2007
Abstract :
Photonic band gap (PBG) materials are 3D periodic dielectrics that enable engineering of the most fundamental properties of electromagnetic waves. Most strikingly, they enable the trapping and localization of light. Unlike electronic micro-circuitry, optical wave-guides in a PBG micro-chip can simultaneously conduct hundreds of wavelength channels of information in a three-dimensional circuit path without loss. I review recent approaches to micro-fabrication of PBG materials, including single-beam optical lithography using a novel optical phase mask. I describe all-optical switching in a PBG wave-guide through coherent resonant interaction with an inhomogeneously broadened distribution of quantum dots. I discuss the possibility of electromagnetically induced exciton mobility in a PBG quantum well hetero-structure.
Keywords :
dielectric materials; integrated optics; masks; micro-optics; optical fabrication; optical waveguides; photolithography; photonic band gap; quantum dots; quantum wells; 3D periodic dielectrics; coherent resonant interaction; electromagnetic waves; electromagnetically induced exciton mobility; electronic microcircuitry; light localization; light trapping; light-matter interactions; microfabrication; optical phase mask; optical switching; optical waveguides; photonic band gap materials; photonic band gap microchip; quantum dots; quantum well heterostructure; single-beam optical lithography; three-dimensional circuit path; wavelength information channels; Circuits; Conducting materials; Dielectric materials; Electromagnetic scattering; Electron traps; Lithography; Optical losses; Optical materials; Photonic band gap; Resonance;
Conference_Titel :
Optical MEMS and Nanophotonics, 2007 IEEE/LEOS International Conference on
Conference_Location :
Hualien
Print_ISBN :
978-1-4244-0641-8
DOI :
10.1109/OMEMS.2007.4373810
