Title :
Guided modes with flat photonic bands in textured metallic microcavities
Author :
Salt, M.G. ; Tan, W.C. ; Barnes, Walter L.
Author_Institution :
Thin Film Photonics Group, Exeter Univ., UK
Abstract :
Summary form only given. The use of planar microcavity structures to control spontaneous emission from optical devices is now a well-established technique. The simplest geometry is that of a pair of planar mirrors separated by a distance of order the wavelength of light, with the emissive species situated between the two mirrors. It has been clearly demonstrated that the boundary conditions imposed by such planar microcavity systems can modify the spatial and spectral distribution of the emitted radiation from such devices, and also the spontaneous emission lifetime of the emitter. However, the extent to which spontaneous emission may be controlled is limited by the planar symmetry of the microcavity. In order to modify the spontaneous emission process further, the dimensionality of the system needs to be reduced, and it is this that we have sought to do in the present study.
Keywords :
cavity resonators; metals; micro-optics; mirrors; optical planar waveguides; optical resonators; optical waveguide theory; photonic band gap; spontaneous emission; texture; boundary conditions; dimensionality; emissive species; emitted radiation; flat photonic bands; guided modes; light wavelength; microcavity; optical devices; planar microcavity structure; planar microcavity systems; planar mirror pair; planar mirrors; planar symmetry; spatial distribution; spectral distribution; spontaneous emission; spontaneous emission lifetime; spontaneous emission process; textured metallic microcavities; Etching; Microcavities; Mirrors; Optical waveguides; Photonic crystals; Physics; Resonance; Silicon; Stimulated emission; Ultrafast optics;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 2000. (QELS 2000). Technical Digest
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
1-55752-608-7
