Title :
Modeling of optical waveguide modulators on III-V semiconductors
Author :
Glingener, C. ; Schulz, D. ; Voges, E.
Author_Institution :
Lehrstuhl fur Hochfrequenztech., Dortmund Univ., Germany
fDate :
1/1/1995 12:00:00 AM
Abstract :
Efficient two-dimensional algorithms for the analysis of optical waveguide modulators are developed. The basic semiconductor equations are solved numerically taking into account carrier degeneracy, heterojunctions, and the nonparabolic band structure of the GaAs- and InP-based III-V compounds. An analytical, semiempirical model is utilized for the fundamental dielectric function. The variation of the dielectric function due to field related and carrier related phenomena, i.e., linear electrooptic-, electrorefractive- and plasma effects, bandfilling and bandgap shrinkage, are considered. The induced anisotropy and losses are described by a dielectric tensor. Therefore, the vectorial wave equation is solved using a perturbation method. The theoretical results are in excellent agreement with experimental data
Keywords :
electro-optical modulation; gallium arsenide; indium compounds; optical losses; optical waveguide theory; optical waveguides; semiconductor device models; semiconductor heterojunctions; semiconductor plasma; GaAs; GaAs-based III-V compounds; III-V semiconductors; InP; InP-based III-V compounds; bandfilling; bandgap shrinkage; basic semiconductor equations; carrier degeneracy; carrier related phenomena; dielectric function; dielectric tensor; electrorefractive; fundamental dielectric function; heterojunctions; induced anisotropy; linear electrooptic; losses; nonparabolic band structure; optical waveguide modulators; plasma effects; semiempirical model; two-dimensional algorithms; vectorial wave equation; Algorithm design and analysis; Analytical models; Dielectric losses; Equations; Heterojunctions; III-V semiconductor materials; Optical modulation; Optical waveguides; Plasma waves; Semiconductor waveguides;
Journal_Title :
Quantum Electronics, IEEE Journal of
