Picosecond infrared double resonance studies on SF6

15 May 1981

journal article
research article
Published by AIP Publishing in The Journal of Chemical Physics

Vol. 74 (10) , 5357-5365
https://doi.org/10.1063/1.440963

Abstract

A classic pump–probe experiment is performed on SF₆. Using 30 psec pulses from two independently tunable CO₂ lasers, we have studied the intramolecular energy transfer processes occurring in a collisionless environment. Distinct from nanosecond pulse experiments, we find an extremely narrow and deep hole burning feature at the pump wavelength. Experimental results exhibit both discrete state bottlenecking effects and quasicontinuum absorption. New evidence of an extremely rapid collisional relaxation is found, which may be related to rotational hole filling.

Keywords

This publication has 25 references indexed in Scilit:

High-resolution double-resonance spectroscopy of 2ν_3 ← ν_3 transitions in SF_6
Optics Letters, 1981
ν_3 vibrational ladder of SF_6
Optics Letters, 1981
Rotational relaxation in the s1(1Au) state of glyoxal
Chemical Physics Letters, 1980
Spectral characteristics of the SF6 molecules excitation by a strong IR laser field at continuously tuned radiation frequency
Optics Communications, 1979
Collisionless multiphoton energy deposition and dissociation of S $F_{6}$
Physical Review A, 1979
Collisionless Intramolecular Vibratonal Relaxation in S $F_{6}$
Physical Review Letters, 1978
IR absorption of highly vibrationally excited SF6
Applied Physics A, 1978
Rotational relaxation in S1 glyoxal: Cross sections and a search for propensity rules
Chemical Physics, 1978
High-resolution transient-double-resonance spectroscopy in SF_6
Optics Letters, 1977
CO₂ Laser-Induced Dissociation of SiF₄ Molecules into Electronically Excited Fragments
Canadian Journal of Physics, 1973