Photoexcited transport in GaAs/AlAs quantum wells
- 18 August 1986
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 49 (7) , 406-408
- https://doi.org/10.1063/1.97602
Abstract
We present the results of a study of the transport of optically excited carriers perpendicular to weakly coupled GaAs/AlAs multiple quantum wells imbedded in the depletion region of a p-i-n photodiode. At temperatures above 120 K the photocurrent was thermally activated. For lower temperatures the photocurrent decreased as temperature was increased. Wavelength-dependent negative differential resistance regions were present in the reverse bias region of the photoexcited current voltage (I-V) curve as a result of the Stark shifts of the lowest energy heavy hole (h1) and light hole (l1) excitons. Additional wavelength independent structure was also visible in the photoexcited I-V curves.Keywords
This publication has 15 references indexed in Scilit:
- Photocurrent spectroscopy of GaAs/As quantum wells in an electric fieldPhysical Review B, 1986
- Lifetime Enhancement of Two-Dimensional Excitons by the Quantum-Confined Stark EffectPhysical Review Letters, 1985
- Spectral and temporal characteristics of AlGaAs/GaAs superlattice p-i-n photodetectorsApplied Physics Letters, 1985
- Effective mass filtering: Giant quantum amplification of the photocurrent in a semiconductor superlatticeApplied Physics Letters, 1985
- Electric field dependence of optical absorption near the band gap of quantum-well structuresPhysical Review B, 1985
- Photoluminescence quenching in reverse-biased As/GaAs quantum-well heterostructures due to carrier tunnelingPhysical Review B, 1985
- Measurements of electric-field-induced energy-level shifts in GaAs single-quantum-wells using electroreflectanceSolid State Communications, 1985
- Optical Absorption of GaAs-AlGaAs Superlattice under Electric FieldJapanese Journal of Applied Physics, 1985
- Effect of an electric field on the luminescence of GaAs quantum wellsPhysical Review B, 1982
- Superlattice band structure in the envelope-function approximationPhysical Review B, 1981