The vibrational relaxation of HCl (υ = 3, 2 and 1) by Cl atoms

The vibrational relaxation of HCl(u= 1) by chlorine and bromine atoms has been me:lsured at 295 K by :I discharge fbW SySti%l using the resonance fluorescence method to dctcct the hiIlogen atom concentration, combined with laser induced tkorescencc. T&c rnessured rate comtants arc: K(HCI-Cl) = (7.0

Vibrational relasatioo of CO2 by Hz0 has been studied theoretiully. Earlier theoretical works are critically analyzed. A new mechanism of V-R-T interaction is put forxvard and a functional equation for the probability factor is obtained. Collisions of CO2 with H-J 0 adsorbed on a solid surface are

The rake constam [or NO+(u) vibrational relaxation by memsrable 02('A ) molecul& is round LO be (3+2)x10-" err? 5-l al room lemperanxc. in comras~ IO the lack of vibrational quenching of NO'(u) by ground-stale 02('X) molecules. [or which the quenching mLe constant <lo-" cm3 s-l. This suggests that N

The vibrational relasation time for COz(v3) + O(3P) has been mcasurcd by Inscr fluorescence. The observed value, pCo2,0 = 0.21 \* 0.04 fiscc, is an order of mqniludc lower than the relaxation time for self-collisions.

Nz(A. u = O-3) produced by the AI(~P~,~) + N2 reaction and detected by laser-induced fluorescence undergoes rapid, stcpwise vibrational relaxation but slow electronic quenching with added CH4 or CF4. Rate constants, k& of 1.5,3.1, and 5.0 X lo-l2 cm3 s-' are measured for Q = CH4, u = 1-3, and O-47,1

## Abstract The rate of vibrational relaxation of HF(__v__ = 1) by F atoms has been calculated using quasi‐classical trajectory techniques. An attempt has been made to account for the effects of multiple potential energy surfaces on the vibrational relaxation efficiency within the electronically ad