DocumentCode :
1137159
Title :
Ultrafast Gain Dynamics in Quantum-Dot Amplifiers: Theoretical Analysis and Experimental Investigations
Author :
van der Poel, Mike ; Gehrig, Edeltraud ; Hess, Ortwin ; Birkedal, Dan ; Hvam, Jorn M.
Author_Institution :
Res. Center COM, Tech. Univ. of Denmark, Lyngby, Denmark
Volume :
41
Issue :
9
fYear :
2005
Firstpage :
1115
Lastpage :
1123
Abstract :
Ultrafast gain dynamics in an optical amplifier with an active layer of self-organized quantum dots (QDs) emitting near 1.3 
is characterized experimentally in a pump-probe experiment and modeled theoretically on the basis of QD Maxwell–Bloch equations. Experiment and theory are in good agreement and show ultrafast subpicoseconds gain recovery followed by a slower 5 ps recovery. This behavior is found to be mainly caused by longitudinal optical phonon scattering and strongly dependents on electronic structure and confinement energy of the dots. A low amplitude-phase coupling ( 
factor) is theoretically predicted and demonstrated in the experiments. The fundamental analysis reveals the underlying physical processes and indicates limitations to QD-based devices.
is characterized experimentally in a pump-probe experiment and modeled theoretically on the basis of QD Maxwell–Bloch equations. Experiment and theory are in good agreement and show ultrafast subpicoseconds gain recovery followed by a slower 5 ps recovery. This behavior is found to be mainly caused by longitudinal optical phonon scattering and strongly dependents on electronic structure and confinement energy of the dots. A low amplitude-phase coupling ( factor) is theoretically predicted and demonstrated in the experiments. The fundamental analysis reveals the underlying physical processes and indicates limitations to QD-based devices.Keywords :
high-speed optical techniques; phonons; quantum dot lasers; semiconductor device models; semiconductor optical amplifiers; 1.3 mum; 5 ps; Maxwell-Bloch equations; confinement energy; electronic structure; low amplitude-phase coupling; optical phonon scattering; pump-probe experiment; quantum-dot amplifiers; self-organized quantum dots; subpicosecond gain recovery; ultrafast gain dynamics; ultrafast gain recovery; Maxwell equations; Optical amplifiers; Optical pumping; Optical scattering; Phonons; Quantum dots; Quantum mechanics; Semiconductor optical amplifiers; Stimulated emission; Ultrafast optics; Quantum dots (QDs); semiconductor optical amplifiers (SOAs); ultrafast optics;
fLanguage :
English
Journal_Title :
Quantum Electronics, IEEE Journal of
Publisher :
ieee
ISSN :
0018-9197
Type :
jour
DOI :
10.1109/JQE.2005.852795
Filename :
1495625
Link To Document :
