Title :
Microscopic Modeling of Quantum Well Gain Media for VECSEL Applications
Author :
Bückers, Christina ; Imhof, Sebastian ; Thränhardt, Angela ; Hader, Jörg ; Moloney, Jerome V. ; Koch, Stephan W.
Author_Institution :
Dept. of Phys., Philipps-Univ. Marburg, Marburg
Abstract :
This paper summarizes a consistent microscopic approach that allows for predictive calculations of laser gain/absorption, photoluminescence, and the intrinsic laser loss processes. The theory is first evaluated for an (AlGaIn)As quantum well system used in a vertical-external-cavity surface-emitting laser structure. Good agreement with experimental results is demonstrated. In a second application, the microscopic approach is used to predict the optical properties of novel dilute bismide containing GaAs-based quantum well gain media. Modeling the bismuth-induced band structure modifications by a valence band anticrossing model, the material gain, radiative, and Auger losses are computed.
Keywords :
III-V semiconductors; aluminium compounds; gallium arsenide; gallium compounds; indium compounds; laser beam applications; laser beams; laser cavity resonators; laser theory; optical losses; optical materials; quantum wells; surface emitting lasers; (AlGaIn)As; Auger losses; GaAs; VECSEL application; band anticrossing model; bismuth-induced band structure; laser gain; material gain; microscopic model; quantum well gain media; vertical-external-cavity surface-emitting laser; Dilute bismide III–V compounds; microscopic laser modeling; quantum well systems; semiconductor gain materials; valence band anticrossing;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2008.2012264
