Title :
Optical gain of interdiffused InGaAs-As and AlGaAs-GaAs quantum wells
Author :
Chan, K.S. ; Li, E. Herbert ; Chan, Michael C Y
Author_Institution :
Dept. of Phys., Hong Kong Univ., Hong Kong
fDate :
1/1/1998 12:00:00 AM
Abstract :
We have analyzed theoretically the effects of interdiffusion on the gain, differential gain, linewidth enhancement factor, and the injection current density of In0.2Ga0.8As-GaAs and Al0.3Ga0.7As-GaAs quantum-well (QW) lasers. We have calculated the electron and hole subband structures including the effects of valence band mixing and strains. The optical gain is then calculated using the density matrix approach. Our results show that the gain spectrum can be blue-shifted without an enormous increase in the injected current density. Imposing an upper limit (416 A·cm-2) on the injection current density for a typical laser structure, we find that the InGaAs-GaAs and AlGaAs-GaAs QW lasers can be blue-shifted by 24 and 54 mn, respectively. Our theoretical results compare well with the tuning ranges of 53 and 66 meV found for AlGaAs-GaAs QWs in some experiments. This indicates that the interdiffusion technique is useful for the tuning of laser operation wavelength for multiwavelength applications
Keywords :
chemical interdiffusion; current density; diffusion; laser theory; laser tuning; quantum well lasers; semiconductor device models; spectral line shift; 53 meV; 66 meV; Al0.3Ga0.7As-GaAs; AlGaAs-GaAs quantum wells; In0.2Ga0.8As-GaAs; QW lasers; blue-shifted; density matrix approach; differential gain; electron subband structures; gain spectrum; hole subband structures; injected current density; injection current density; interdiffused InGaAs-As quantum wells; laser tuning; linewidth enhancement factor; multiwavelength applications; optical gain; quantum-well lasers; tuning ranges; typical laser structure; valence band mixing; Charge carrier processes; Current density; Impurities; Laser theory; Laser tuning; Optical device fabrication; Optical mixing; Photonic band gap; Quantum well lasers; Semiconductor lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
