Rotational energy distributions of benzene liberated from aqueous liquid microjets: A comparison between evaporation and infrared desorption

Rotational energy distributions of benzene liberated from aqueous liquid microjets: A comparison between evaporation and infrared desorption

We have measured the rotational energy distribution of benzene molecules both evaporated and desorbed by an IR laser from a liquid microjet. Analysis of the 6(0)(1) vibronic band of benzene has shown that the benzene molecules evaporating from the liquid microjet surface have a rotational temperatur...

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Bibliographic Details
Main Authors: Maselli, O., Gascooke, J., Kobelt, S., Metha, G., Buntine, Mark
Format: Journal Article
Published: CSIRO Publishing 2006
Subjects:
SOLVENT
WATER
MOLECULAR-BEAM
IONIZATION
NEUTRAL CLUSTERS
LASER-DESORPTION
IRRADIATION
IR LASER
IONIZATION/DESORPTION MASS-SPECTROMETRY
COMPLEXES
Online Access:http://hdl.handle.net/20.500.11937/31079
Description
Summary:We have measured the rotational energy distribution of benzene molecules both evaporated and desorbed by an IR laser from a liquid microjet. Analysis of the 6(0)(1) vibronic band of benzene has shown that the benzene molecules evaporating from the liquid microjet surface have a rotational temperature of 157 +/- 7 K. In contrast, the rotational temperature of benzene molecules desorbed from the liquid microjet by a 1.9 mu m laser pulse is 82 +/- 5 K. However, in both cases careful inspection of the spectral profiles shows that the experimental rotational distributions are non-Boltzmann, displaying an underpopulation of high rotational states and a relative overpopulation of the low rotational states. The non-equilibrium evaporation and desorption spectral profiles are consistent with a model that involves transfer of internal energy into translation upon liberation from the condensed phase.

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