We have investigated optical orientation in the vicinity of the direct gap of bulk germanium. The electron spin polarization is studied via polarization-resolved photoluminescence excitation spectroscopy unfolding the interplay between doping and ultrafast electron transfer from the center of the Brillouin zone towards its edge. As a result, the direct-gap photoluminescence circular polarization can vary from 30% to -60% when the excitation laser energy increases. This study provides also simultaneous access to the resonant electronic Raman scattering due to inter-valence-band excitations of spin-polarized holes, yielding a fast spectroscopic approach for the determination of the energy spectrum of holes in semiconducting materials.
Pezzoli, F., Balocchi, A., Vitiello, E., Amand, T., Marie, X. (2015). Optical orientation of electron spins and valence-band spectroscopy in germanium. PHYSICAL REVIEW. B, CONDENSED MATTER AND MATERIALS PHYSICS, 91(20) [10.1103/PhysRevB.91.201201].
Optical orientation of electron spins and valence-band spectroscopy in germanium
PEZZOLI, FABIOPrimo
;VITIELLO, ELISA;
2015
Abstract
We have investigated optical orientation in the vicinity of the direct gap of bulk germanium. The electron spin polarization is studied via polarization-resolved photoluminescence excitation spectroscopy unfolding the interplay between doping and ultrafast electron transfer from the center of the Brillouin zone towards its edge. As a result, the direct-gap photoluminescence circular polarization can vary from 30% to -60% when the excitation laser energy increases. This study provides also simultaneous access to the resonant electronic Raman scattering due to inter-valence-band excitations of spin-polarized holes, yielding a fast spectroscopic approach for the determination of the energy spectrum of holes in semiconducting materials.
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