Title :
Coupled defects in photonic crystals
Author :
Reynolds, Andrew L. ; Peschel, Ulf ; Lederer, Falk ; Roberts, Peter John ; Krauss, Thomas F. ; De Maagt, Peter J I
fDate :
10/1/2001 12:00:00 AM
Abstract :
We present a theoretical and numerical description of coupled defects in photonic-bandgap crystals, expandable to cover a wide range of applications. Based on a weak interaction approach, explicit expressions are derived for defect interaction. The basis is formed by a system of coupled ordinary differential equations for the field amplitudes for individual defects. The actual configuration of the defects (chain, lattice, bend, or anything else) enters the equations as a linear coupling between neighboring defects. The strength of this method is that many solutions of this system are known analytically; the band structure as well as the transmission response of a defect chain, or of a defect lattice, can be determined. The results for the superlattice of defects are compared with widely accepted numerical methods, the transfer matrix method, and finite-difference time domain method
Keywords :
differential equations; electromagnetic wave propagation; numerical analysis; periodic structures; photonic band gap; superlattices; EM crystals; PBG crystals; band structure; coupled defects; coupled ordinary differential equations; defect interaction; electromagnetic crystals; field amplitudes; field propagation; photonic-bandgap crystals; superlattice; transmission response; weak interaction approach; Couplings; Dielectrics; Dispersion; Electromagnetic waveguides; Lattices; Personal communication networks; Photonic band gap; Photonic crystals; Space technology; Superlattices;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
