Title :
Excited-state gain dynamics in InGaAs quantum-dot amplifiers
Author :
Schneider, S. ; Borri, P. ; Langbein, W. ; Woggon, U. ; Sellin, R.L. ; Ouyang, D. ; Bimberg, D.
Author_Institution :
Fachbereich Phys., Univ. Dortmund, Germany
Abstract :
The ultrafast gain recovery dynamics of the first excited state (ES) is studied in an electrically pumped InGaAs quantum-dot amplifier at room temperature and compared with the ground-state (GS) gain dynamics. Pump-probe differential transmission experiments are performed in heterodyne detection and the gain dynamics are investigated as a function of injection current. An ultrafast (<200 fs) initial gain recovery of both GS and ES transition is found, promising for optical signal processing at high bit rates. The obtained results suggest the occurrence of a fast recovery of the state occupation mediated by carrier-carrier scattering as long as a reservoir of carriers in the ESs and wetting layer is present.
Keywords :
III-V semiconductors; electron beam pumping; excited states; gallium arsenide; heterodyne detection; high-speed optical techniques; indium compounds; quantum dot lasers; semiconductor optical amplifiers; 293 to 298 K; InGaAs; InGaAs amplifiers; carrier-carrier scattering; electrically pumped amplifier; excited-state gain dynamics; gain dynamics; ground-state gain dynamics; heterodyne detection; injection current; optical signal processing; pump-probe differential transmission; quantum-dot amplifiers; room temperature; state occupation; ultrafast gain recovery; wetting layer; Bit rate; Indium gallium arsenide; Optical amplifiers; Optical scattering; Optical signal processing; Particle scattering; Performance gain; Quantum dots; Reservoirs; Temperature; Amplifiers; quantum dots (QDs); semiconductor devices; semiconductor lasers; spectroscopy;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2005.856446
