Title :
Generation of coherent phonons in condensed media
Author :
Kütt, Waldemar A. ; Albrecht, Wolfgang ; Kurz, Heinrich
Author_Institution :
Inst. of Semicond. Electron., RWTH Aachen, Germany
fDate :
10/1/1992 12:00:00 AM
Abstract :
The generation of coherent phonons by absorption of femtosecond laser pulses through interband transitions in different materials is summarized. Starting with layered III-VI semiconductors, where optical excitation is performed with amplified pulses, the generation mechanism via strong interband transitions is investigated. In Ge, stimulated resonant Raman scattering is found to be the decisive driving force. In GaAs, however, the ultrafast screening of surface space charge fields launches LO-phonons via electrostatic coupling. In the metallic state of high-temperature superconductors, the generation of highly symmetric Ag modes is assigned to displacive processes induced by a nonequilibrium electronic carrier distribution. In the superconducting state the amount of coherent displacement is strictly correlated to the number of optically broken superconducting pairs. In addition to the comparison of various generation processes, the dephasing of coherent phonons is addressed
Keywords :
III-VI semiconductors; gallium arsenide; gallium compounds; germanium; high-temperature superconductors; indium compounds; lattice phonons; nonlinear optics; semiconductors; stimulated Raman scattering; GaAs; GaSe; Ge; InSe; LO-phonons; YBa2Cu3O7-x; amplified pulses; coherent displacement; coherent phonon dephasing; coherent phonon generation; condensed media; displacive processes; electrostatic coupling; femtosecond laser pulse absorption; high-temperature superconductors; highly symmetric Ag modes; interband transitions; layered III-VI semiconductors; metallic state; nonequilibrium electronic carrier distribution; optical excitation; optically broken superconducting pairs; stimulated resonant Raman scattering; superconducting state; surface space charge fields; ultrafast screening; Absorption; High temperature superconductors; Laser transitions; Optical pulse generation; Optical scattering; Phonons; Pulse amplifiers; Semiconductor lasers; Ultrafast electronics; Ultrafast optics;
Journal_Title :
Quantum Electronics, IEEE Journal of
