Optoacoustic study of the infrared multiphoton excitation of ethylene

A method is offered to estimate quantitatively the energy distribution of molecules reacting after being excited by multiphoton absorption of infrared radiation. The method is based on the comparison of the real time reaction kinetics obtained in the infrared multiphoton experiment with those observ

The dependence of collisionless multiphoton excitation on the laser polarization is theoretically discussed and esperimentally observed in SFe irradiated by a TEA COP laser.

SO? molecules excited under essentialIp collision-free conditions by intense (>20 G\V]cm') COP laser pulses @ve off a broad UV-visible luminescence through inverse electronic relaxation. Unlike in lager polyatomics, the infrared multiphoton escitation process is controlled by the laser intensity and

We investigated the infrared multiphoton excitation of SO2 in bulk samples and in a supersonic jet with the 9R1,22), 9R(32), and 9P( 32) CO\*-laser lines. Coherent anti-Stokes Raman spectra reveal unambiguously that only the v,-mode at II5 I .3 cm-' is actually pumped; no 2vl overtone pumping at 103

## Chssical trajectories on a realistic model potential energy surface (approximating one dissociation channel of CD&I) driven by \_an external force have been used to mode: infrared multiphoton dissociation. This model predicts a reasonable energy density threshold behavior, and generally (except