Title :
Modeling of optical gain in InGaN-AlGaN and InxGa1-xN-InyGa1-yN quantum-well lasers
Author :
Jain, F. ; Huang, W.
Author_Institution :
Dept. of Electr. & Syst. Eng., Connecticut Univ., Storrs, CT, USA
fDate :
5/1/1996 12:00:00 AM
Abstract :
This paper presents computations of the optical gain in Inx Ga1-xN-InyGa1-yN and InGaN-AlGaN quantum-well lasers involving the contributions of excitons as well as free carriers transitions. The behavior of optical gain in GaN based quantum wells due to excitonic transitions is quite similar to that of ZnCdSe-ZnSSe system, as the magnitude of the exciton binding energies (~30 meV) is comparable. The model compares the exciton emission energy with the experimental data reported on In0.22Ga0.78N-In0.06Ga0.94N multiple quantum wells as well as in GaN layers (cubic grown on 3C SiC), including the effect of strain induced band gap changes. The optical gain is also computed as a function of the injection current density for the InGaN-AlGaN multiple quantum-well lasers. The model evaluates the feasibility of obtaining GaN based blue and ultraviolet lasers. It is shown that the excitonic transitions reduce the threshold current density which is adversely affected by the presence of dislocations and other defects
Keywords :
III-V semiconductors; aluminium compounds; binding energy; current density; energy gap; excitons; gallium compounds; indium compounds; laser theory; laser transitions; quantum well lasers; semiconductor device models; GaN layers; In0.22Ga0.78N-In0.06Ga0.94 N multiple quantum wells; InxGa1-xN-InyGa1-yN quantum-well lasers; InGaN-AlGaN; InGaN-AlGaN multiple quantum-well lasers; SiC; ZnCdSe-ZnSSe system; cubic grown; defects; dislocations; exciton binding energies; excitonic transitions; excitons; free carriers transitions; injection current density; optical gain; quantum-well lasers; strain induced band gap changes; threshold current density; ultraviolet lasers; Capacitive sensors; Current density; Excitons; Gallium nitride; Optical computing; Photonic band gap; Quantum computing; Quantum well lasers; Silicon carbide; Stimulated emission;
Journal_Title :
Quantum Electronics, IEEE Journal of
