Mechanism for reducing recovery time of optical nonlinearity in semiconductor laser amplifier
- 25 May 1998
- journal article
- conference paper
- Published by AIP Publishing in Applied Physics Letters
- Vol. 72 (21) , 2657-2659
- https://doi.org/10.1063/1.121089
Abstract
We propose and demonstrate a novel scheme to reduce the recovery time of optical nonlinearity in a semiconductor laser optical amplifier driven under a loss condition for the signal light pulse. Additional light, which is set at a transparency wavelength in the active layer, promotes stimulated recombination of excess carriers induced by the absorption of the signal light. This scheme excludes any additional carrier transport mechanism and nonradiative recombination and hence generation of heat. The principle of operation is experimentally verified by measuring time-domain transmission variance using a pump–probe method. A drastic reduction of the excess-carrier lifetime to less than 70 ps was confirmed.Keywords
This publication has 13 references indexed in Scilit:
- High-repetition operation of a symmetric Mach–Zehnder all-optical switchApplied Physics Letters, 1995
- 10 ps pulse all-optical discrimination using a high-speedsaturable absorber optical gateElectronics Letters, 1995
- All-optical picosecond switching of a quantum well etalon using spin-polarization relaxationApplied Physics Letters, 1995
- Subpicosecond gain and index nonlinearities in InGaAsP diode lasersOptics Communications, 1994
- Ultrafast dynamics in field-enhanced saturable absorbersApplied Physics Letters, 1994
- Above- and below-band femtosecond nonlinearities in active AlGaAs waveguidesApplied Physics Letters, 1992
- Subpicosecond gain dynamics in InGaAsP optical amplifiers: Experiment and theoryApplied Physics Letters, 1992
- Fast Recovery from Excitonic Absorption Bleaching in Type-II GaAs/AlGaAs/AlAs Tunneling Biquantum WellJapanese Journal of Applied Physics, 1992
- Observations of ultrafast nonlinear refraction in an InGaAsP optical amplifierApplied Physics Letters, 1991
- Femtosecond gain dynamics and saturation behavior in InGaAsP multiple quantum well optical amplifiersApplied Physics Letters, 1990