The vibrational deactivation of the bending mode of CO2 by O2 and by N2

## Energy transfer between vibrationally excited CO and COz has been used to excite the bendini mode of COa. The rate of deactivation of this mode by CO\* and by Ar has been measured down to 150 K. The followïng processes were considered CO@= 1) + co,(ooo) Ke 5 CO(u=O) + CO,(OOl), AE = t206 crneL

The deactivation of C&(OO"l) by ethane in.ihe temperature ran9 300-600 K has been strrdied using 2 laser induced fluorescence technique. Thhd energ transfer cross section dccrased from 0.23 A2 at 3CO K to 0.16 AZ at 600 K. The magnitude of the cross section is consistent with the expectation that nc

The rate constrtnt k& of the dcxtiration of the states (02'0. lO\*O)t. (O;Z'O. 10'O)t1 and (OZ20), assumed in mutual equilibrium, 10wmis (01'0) is mrxwmxf betaecn 170 nnd 300 Kc; the rate constant KbS nbich characterizes the deactivation of aLI r)mmetric-strctching and bertdins ItwIs is measured fro

have been performed with the laser excited fluorescence method of the rates of vibratianal drcrctivation of the upper CO2 laser level by ONF, COF;? and 03. In each cast, rapid near-resonant V + V transfer deactivation mechanisms are indicated.

Rate constants are reported for the vibrational deactivation of the asymmetric stretching mode of NsO in the gas phase over the temperature range 300-150 K. Experimental pressures varied between 10 and 600 Torr. The collision partners studied are NsO itself, 02, N2 and CH+ The measurements were made

A photoacoustic method is used under such experimental conditions that the (01'0) level ofC02 gas is not in e@li%rinrn with the other vibrational Ievck The rate mnsta.ntsk;o characterizing the CO2 (01'0) collisional deactivation by Nz, CO aad 02 are measured directly.