A comment on the vibrational distribution of CO produced by the reaction of O with CS and CS2

## CS? in an Ar afterglow eshibircd rrnission from the 0'. 1' and 2' levels of CSG(x 'n,-% 'II,). The excitation source was attributed to Ar;. The vibrational frequencies of CS;(.?: U: = 4 and u'; + $u: = 3) were detcrkined from the vibrational analysis of the (u'; ,&.O) progressions from the O" l

Infrared emission (Au --2) has been observed from NO (u = 2-7) produced by the reaction N&3 f @ + NO(v) + 0. The apparent NO vibrational energy distribution is different from the distribution initially produced by the reaction owing to stepwise V-V quenching of NO(u) by collision with 02. A time-to

The populations of the nascent CO formed in the reactions oi COS with 0(3P~) and O(" Dz) atoms: O? P) + cos s co? + so, O(' D) c COS 4 COi + SO have been determined by a CO laser resonant absorption method. The fraction of the total available energy channelled into CO as vibration ~1s calculated to

A'flow-tube technique has Seen developed for studying the kinetics of elementary reactions of gaseous monomeric. CS. CYbon.monosulphide is generated by means of a low-power electrcddkless discharge in a dilute CSz/Ar stream, fo which reactive gazes may be added through a moveable injector. Detection

CO\*(A "ll-X 2P) emission produced from the C(2P) + O2 reaclm hss been observed al thermal cncrgy III a flowing afterdow apparatus. The relabve vIbrational population In the CO\*(A %I) state was dctcrrnmcd The avcngc fmctlon of VIbntional cncrgy dwrbulcd m CO+(A Zn).(/vJ. ws estimated to be 0.20 i 0