Coulomb Damped Relaxation Oscillations in Semiconductor Quantum Dot Lasers

Coulomb Damped Relaxation Oscillations in Semiconductor Quantum Dot Lasers

We present a theoretical simulation of the turn-on dynamics of InAs/GaAs quantum dot semiconductor lasers driven by electrical current pulses. Our approach goes beyond standard phenomenological rate equations. It contains microscopically calculated Coulomb scattering rates, which describe Auger tran...

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Veröffentlicht in:IEEE journal of selected topics in quantum electronics 2007-09, Vol.13 (5), p.1242-1248
Hauptverfasser: Malic, E., Bormann, M.J.P., Hovel, P., Kuntz, M., Bimberg, D., Knorr, A., Scholl, E.
Format: Artikel
Sprache:eng
Schlagworte:
Coulomb friction
Coulomb scattering rates
Equations
Gallium arsenide
Laser theory
Laser transitions
Lasers
Mathematical analysis
Microscopy
Nanostructure
Optical pulses
Particle scattering
quantum dot (QD) lasers
Quantum dot lasers
Quantum dots
Quantum mechanics
Relaxation oscillations
Semiconductor lasers
Semiconductors
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Beschreibung
Zusammenfassung:We present a theoretical simulation of the turn-on dynamics of InAs/GaAs quantum dot semiconductor lasers driven by electrical current pulses. Our approach goes beyond standard phenomenological rate equations. It contains microscopically calculated Coulomb scattering rates, which describe Auger transitions between quantum dots and the wetting layer. In agreement with the experimental results, we predict a strong damping of relaxation oscillations on a nanosecond time scale. We find a complex dependence of the Coulomb scattering rates on the wetting layer electron and hole densities, and we show their crucial importance for the understanding of the turn-on dynamics of quantum dot lasers.
ISSN:1077-260X
1558-4542
DOI:10.1109/JSTQE.2007.905148