Title :
Two-dimensional photonic crystals: waveguides and guided resonance
Author_Institution :
Ginzton Lab., Stanford Univ., CA, USA
Abstract :
A general designing procedure is introduced that allows for any given photonic crystal slab, to create an appropriate waveguide structure that possesses single-mode bands with large bandwidth and low dispersion within the photonic band gap below the light line. The procedure consists of two steps: i) designing a conventional dielectric waveguide that is optimally phase matched with the band gap of the photonic crystal slab; and ii) embedding the dielectric waveguide into the photonic crystal in an appropriate way such that the edge states are eliminated and single mode propagation is ensured. This procedure produces waveguide structures with large bandwidth of single mode and lossless propagation, and creates dispersion relations that are essentially linear over most of the guiding bandwidth.
Keywords :
integrated optics; optical design techniques; optical dispersion; optical losses; optical phase matching; optical waveguide theory; permittivity; photonic band gap; photonic crystals; resonant states; dielectric waveguide; dispersion relations; edge states; guided resonance; guiding bandwidth; lossless propagation; phase matching; photonic band gap; photonic crystal slab; single mode propagation; single-mode bands; two-dimensional photonic crystals; waveguides; Bandwidth; Dielectrics; Frequency conversion; Optical losses; Photonic band gap; Photonic crystals; Propagation losses; Resonance; Slabs; Waveguide discontinuities;
Conference_Titel :
Holey Fibers and Photonic Crystals/Polarization Mode Dispersion/Photonics Time/Frequency Measurement and Control, 2003 Digest of the LEOS Summer Topical Meetings
Conference_Location :
Vancouver, BC, Canada
Print_ISBN :
0-7803-7982-9
DOI :
10.1109/LEOSST.2003.1224253
