Title :
Ultrafast spectroscopic tool for studying molecular dissociation
Author :
Senin, A.A. ; Lu, Z. ; Allen, J.R. ; Eden, J.G.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL, USA
Abstract :
In summary, the results of the time-frequency analysis of the output radiation suggest that the dissociation of electronically-excited molecules can be detected with an atomic wavepacket and four-wave mixing. The arrival of the dissociation transient is evidenced by changes in the temporal history of frequency components of the wavepacket. Thus, the technique presented in this work appears to be a novel, powerful spectroscopic tool for studying the dissociation of molecules. The potential of this technique for other molecules and optoelectronic materials (such as rare earth-doped crystals) will be discussed.
Keywords :
high-speed optical techniques; multiwave mixing; photodissociation; rubidium; time resolved spectra; transients; Rb; Rb2; atomic wavepacket; dissociation; dissociation transient; electronically-excited molecules; four-wave mixing; frequency components; laser-induced fluorescence; molecular photodissociation; output radiation; powerful spectroscopic tool; rare earth-doped crystals; rubidium number density; rubidium vapour; third-order susceptibility; time-frequency analysis; wavepacket; Absorption; Atomic beams; Delay effects; Fluorescence; Four-wave mixing; Fourier transforms; Laser theory; Optical modulation; Optical pulses; Spectroscopy;
Conference_Titel :
Lasers and Electro-Optics Society, 2002. LEOS 2002. The 15th Annual Meeting of the IEEE
Print_ISBN :
0-7803-7500-9
DOI :
10.1109/LEOS.2002.1134030
