Title :
Rate equation model for nonequilibrium operating conditions in a self-organized quantum-dot laser
Author :
Huang, H. ; Deppe, D.G.
Author_Institution :
Microelectron. Res. Center, Texas Univ., Austin, TX, USA
fDate :
5/1/2001 12:00:00 AM
Abstract :
A nonequilibrium rate equation model is presented and analyzed for the self-organized quantum dot (QD) laser. The model assumes the QD zero dimensional levels are coupled to a thermal electron distribution in the wetting layer through reservoir rate equations. By including the energy dependence of the wetting layer reservoir versus temperature, the model accounts for the spectral narrowing of the gain with increasing temperature, the negative temperature coefficient of the lasing threshold, and a reduction of the spectral hole burning with increasing temperature, all found experimentally in QD lasers
Keywords :
current density; laser beams; laser theory; optical hole burning; population inversion; quantum well lasers; self-adjusting systems; semiconductor quantum dots; spectral line narrowing; spontaneous emission; wetting; energy dependence; gain; increasing temperature; lasing threshold; negative temperature coefficient; nonequilibrium operating conditions; nonequilibrium rate equation model; quantum dot zero dimensional levels; rate equation model; reservoir rate equations; self-organized quantum dot laser; self-organized quantum-dot laser; spectral hole burning; spectral narrowing; thermal electron distribution; wetting layer; wetting layer reservoir; Equations; Laser modes; Laser theory; Quantum dot lasers; Quantum well lasers; Reservoirs; Surface emitting lasers; Temperature dependence; Temperature distribution; Vertical cavity surface emitting lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
