Energy partitioning and reaction dynamics in the chemiluminescent channel of the reaction: HS + O3 → HSO* + O2

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

The internal energy of the excited BaO formed in the reaction between Ba(6s5d 'D2) and an OZ molecule has been studied in a crossed beam apparatus as a function of the collision energy. It is found to be statistically distributed even at a collision energy as high as 0.58 eV. By comparison with the

A crossed beam study of CO+ production from the C+ + 0s reaction at a collision energy of 0.57 eV is presented. Very clear collision complex dynamics are observed which are shown to be consistent with the decay of a transient complex having a lifetime of approximately 0.5 ps. An analysis of the reac

The chemiluminescent emission from the electronically encited state of HNO ('A") was observed in the r&&ions of O$P)/O, with NO ard one oracetylene, ethylene, propylene, formaldehyde and acetaldehyde. The identification of the emitting species WS'BS confirmed by observing the emission from DNO ti th

Pub~~ed dz~ta on the photoclectmn spectra of NO and 02 ax analyzed, and the energy distributions are found to have averages proportional to the available energy. Hence, vibration rakes a corm=-urtrnction ofthccncrgy. Average distibwions are found CG nfunction of the fraction ofnvdl&ieencr=y.