Title :
Quantum dot photonic devices for lightwave communications
Author_Institution :
Inst. fur Festkorperphys., Technische Univ. Berlin, Germany
Abstract :
Semiconductor quantum dots (QDs) have appealed to physicists and engineers since many years due to their ultimate carrier confinement. The new, realistic models of quantum dot lasers close to reality are based on strained heterostructures, finite barriers, many electron and hole levels, monomolecular (excitonic) recombination and non-equilibrium carrier distribution. The use of GaAs-based QDs in diode lasers and amplifiers at telecom wavelengths has been demonstrated to yield a large number of decisive advantages for systems, both from point of view of performance and of cost. For future metropolitan area networks the demand for inexpensive ultrafast amplifier is probably larger that of lasers. Semiconductor optical amplifiers (SOAs) are expected to play a decisive role here.
Keywords :
III-V semiconductors; gallium arsenide; quantum dot lasers; semiconductor optical amplifiers; semiconductor quantum dots; GaAs; GaAs based QDs; carrier confinement; diode lasers; electron levels; excitonic recombination; finite barriers; hole levels; lightwave communications; monomolecular recombination; nonequilibrium carrier distribution; semiconductor optical amplifiers; semiconductor quantum dot photonic devices; strained heterostructures; telecom wavelengths; ultrafast amplifiers; Carrier confinement; Charge carrier processes; Laser modes; Laser theory; Optical amplifiers; Quantum dot lasers; Quantum dots; Radiative recombination; Semiconductor lasers; Semiconductor optical amplifiers;
Conference_Titel :
Compound Semiconductors, 2003. International Symposium on
Print_ISBN :
0-7803-7820-2
DOI :
10.1109/ISCS.2003.1239920
