Femtosecond spin-polarization spectroscopy in diluted-magnetic-semiconductor quantum wells
- 14 May 1990
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 64 (20) , 2430-2433
- https://doi.org/10.1103/physrevlett.64.2430
Abstract
Charge-carrier spin scattering in diluted-magnetic-semiconductor multiple quantum wells is directly observed through the circular polarization of luminescence in a femtosecond time-resolved measurement. This represents a new short-time regime for direct spin-relaxation studies. Separate observations of electron and hole relaxation are accomplished by varying the applied magnetic field. Surprisingly, the spin-flip scattering rates in these systems appear to be independent of the extremely strong spin-spin–exchange interaction between the charge carriers and the magnetic ions.Keywords
This publication has 11 references indexed in Scilit:
- Spin conservation of photocreated carriers in quantum wells in high magnetic fields: A new spectroscopic toolPhysical Review Letters, 1989
- Spin-dependent type-I, type-II behavior in a quantum well systemPhysical Review Letters, 1989
- Photoinduced magnetization in dilute magnetic (semimagnetic) semiconductorsPhysical Review B, 1989
- ErAs epitaxial layers buried in GaAs: Magnetotransport and spin-disorder scatteringPhysical Review Letters, 1989
- Diluted magnetic semiconductor superlattices for magnetic studies of dimensional crossover (invited)Journal of Applied Physics, 1988
- Ultrafast luminescence spectroscopy using sum frequency generationIEEE Journal of Quantum Electronics, 1988
- Dimensional-crossover studies of magnetic susceptibility in diluted-magnetic-semiconductor superlatticesPhysical Review Letters, 1987
- MBE growth of films and superlattices of diluted magnetic semiconductorsJournal of Vacuum Science & Technology B, 1985
- Properties of Cd1−xMnxTe–CdTe superlattices grown by molecular beam epitaxyJournal of Vacuum Science & Technology B, 1985
- An optical up-conversion light gate with picosecond resolutionOptics Communications, 1975