Deactivation of vibrationally excited N2 by H2O

Using laser-induced fluorescence of ozone (to measure the rate of disappearance of Os?) and NOz titration (to determine 0 atom concentrations), we have determined bimolecular rate constants for the deactivation by 0(3? atoms) of ozone in excited stretching and bending modes. These experiments do not

## A recently developed photoioniz2tion technique for detection of vibratiorally-cxcited nitr~gcn (N$ has been applied to study the quenching of N2 by 0 at 300°K. The rate coefficient for qnenching of Na by 0 is found to be (3.5~1.4)x10-~5 cm3 set-1. The efficient vibrational relaxation previousl

## Abstract Measurements have been made which provide information concerning the rate of energy transfer between vibrationally excited HF and atomic fluorine. It was found that HF (__v__ = 1) deactivates about seven times slower than was determined in previous experiments. The deactivation rate con

The relation between the high-temperature and room-temperature structure of CsCuCl3 -C.J. Kroese and W.J.A. Maaskant.

Comcll l.hiwrsit\_s. Baker Laborarop. Ilhaca. Vch l'orh l-LM\_? L\*Srl NEIL-c~x~dc UI c" 6 11 her been dcrccred using onr-photon rcsonanf laser ion-uation spectroscopy following the reac-

Rate coefficients for the reactions ofSH+NzO(v,, 0, O)+HSO(A\*A') for vi=0 and 1, and HSO(A2A') +N,O+products, are measured at room temperature. SH is formed by pulsed laser photolysis of H2S and vibrationally excited N20 is created using the stimulated Raman technique. The reaction kinetics are fol