Author :
Wiedenhaus, Marco ; Ahland, Andreas ; Schulz, Dirk ; Voges, Edgar
Abstract :
For the design and development of optical semiconductor devices based on quantum-well structures, the investigation of saturation phenomena is necessary for high optical power operation. By applying stationary physical models, nonlinear effects cannot be described adequately; hence, transient models are important for an accurate analysis. By utilizing transient models, saturation phenomena, signal delays, and distortions can be investigated. For the analysis of integrated optoelectronic devices, such as lasers and modulators, transient transport or density matrix equations for carriers and photons and the Poisson equation have to be solved self-consistently. A transient model which is useful for the investigation of a wide range of optoelectronic applications is presented. Quantum optical phenomena are included by applying the interband density matrix formalism in real-space representation, where the Coulomb singularity is treated exactly in the limits of the discretization. As we focus on electroabsorption modulators, a drift-diffusion model adequately approximates the transport properties. Here, quantum effects are considered by a quantum correction, the Bohm potential. The model is applied to investigate transport effects in InP-based waveguide electroabsorption modulators including strained lattices
Keywords :
III-V semiconductors; Poisson equation; electro-optical modulation; electroabsorption; indium compounds; integrated optoelectronics; optical design techniques; optical saturation; optical waveguide components; quantum well devices; semiconductor quantum wells; Bohm potential; Coulomb singularity; InP; InP-based waveguide electroabsorption modulators; Poisson equation; accurate analysis; carriers; density matrix equations; design; development; discretization; drift-diffusion model; dynamical simulation; electroabsorption modulators; high optical power operation; integrated optoelectronic devices; interband density matrix formalism; lasers; modulators; nonlinear effects; optical semiconductor devices; optoelectronic applications; photons; quantum correction; quantum effects; quantum optical phenomena; quantum-well structures; real-space representation; saturation phenomena; signal delays; signal distortions; stationary physical models; strained lattices; transient model; transient models; transient transport; transport effects; transport properties; Nonlinear optical devices; Nonlinear optics; Optical devices; Optical distortion; Optical modulation; Optical saturation; Quantum well devices; Quantum wells; Transient analysis; Transmission line matrix methods;
