ENERGY PARTITIONING FOLLOWING THE IR PHOTOFRAGMENTATION OF SF6-CENTER-DOT(NO)(N)(+) CLUSTER IONS

Using two separate IR lasers, we have attempted to characterise the in crease in internal temperature that should accompany the partitioning of a single quantum of vibrational energy within small SF6 . (NO)(n)() cluster ions. An initial temperature is established by measuring a k inetic-energy release associated with the unimolecular (metastable) de cay of each ion. Using a CO2 laser, ca. 950 cm(-1) of the vibrational energy is deposited into the SF6 moiety and with a CO laser, the (NO)( n)(+) moiety is excited with ca. 1700 cm(-1) of vibrational energy. In both cases, the ions are observed to photo-dissociate and the corresp onding kinetic-energy releases are measured. Using Klots' model (J. Ch em. Phys., 1973, 58, 5364), an attempt is made to predict the photofra gment kinetic energies on the assumption that the energy of each photo n is partitioned statistically and contributes to an overall increase in temperature for each ion. The results show that at the higher photo n energy, events are dominated by angular momentum conservation; a fac tor that is not an integral part of the model. In contrast, the photoe xcitation of SF6 at ca. 950 cm(-1) appears to result in incomplete ene rgy randomisation.