Title :
Femtosecond optical nonlinearities of CdSe quantum dots
Author :
Peyghambarian, Nasser ; Fluegel, Brian ; Hulin, Danièle ; Migus, Arnold ; Joffre, Manuel ; Antonetti, André ; Koch, Stephan W. ; Lindberg, Markus
Author_Institution :
Opt. Sci. Center, Arizona Univ., Tucson, AZ, USA
fDate :
12/1/1989 12:00:00 AM
Abstract :
Femtosecond differential absorption measurements of the quantum-confined transitions in CdSe microcrystallites are reported. Spectral hole burning is observed, which is accompanied by an induced absorption feature on the high-energy side. The spectral position of the burned hole depends on the excitation wavelength. For excitation on the low-energy side of the lowest quantum-confined transition, a slight shift of the hole towards the line center is observed. The hole width increases with pump intensity and the magnitude of the induced transparency saturates at the highest excitation level. The results are consistently explained by bleaching of one-pair states and induced absorption caused by the photoexcited two electron-hole pair states. It is concluded that the presence of one electron in the excited state prevents further absorption of photons at the pair-transition energy and accounts for the major portion of the bleaching of the transition
Keywords :
II-VI semiconductors; cadmium compounds; high-speed optical techniques; optical hole burning; optical pumping; self-induced transparency; semiconductor quantum wells; visible spectra of inorganic solids; CdSe quantum dots; II-VI semiconductor; bleaching; burned hole; burned hole shifts; differential absorption measurements; excitation level; excitation wavelength; femtosecond absorption measurements; femtosecond optical nonlinearities; hole width; induced absorption feature; induced transparency; line center; lowest quantum-confined transition; microcrystallites; one electron; one-pair states; pair-transition energy; photoexcited two electron-hole pair states; photon absorption; pump intensity; quantum-confined transitions; spectral hole burning; spectral position; transition bleaching; Absorption; Bleaching; Boundary conditions; Charge carrier processes; Excitons; Lattices; Potential well; Quantum dots; US Department of Transportation; Ultrafast optics;
Journal_Title :
Quantum Electronics, IEEE Journal of
