The influence of reactant vibrational excitation on the O(3P) + O†3 bimolecular reaction rate

## ~~ ~ Rate constants for the gas-phase reactions of O(3P) atom with a series of rnonoterpenes have been determined at ambient temperature (ca. 302-309 K ) and atmospheric pressure using a relative rate technique Using the literature rate constants for O(3P) + isobutene, cis and trans-2-butene, 3

the formation of higher oxides of chlorine such as Cl 2 O 4 , Cl 2 O 6 , and Cl 2 O 7 has been observed [5 -8]. The reaction mechanisms are not understood but may involve the formation of ClO 3 which has recently been observed in an inert matrix [9]. In these systems, ClO 3 can be formed via the add

The O(3P) + CION reaction has been studicd in a fast flow system over the temperature range from 213 to 295 K, using the air-aftereIow technique for the detection of oxygen atoms under pseudo first order conditions. A value of (3.4 z 0.6) x 10-" exp[(-840 + 60)/T] cm3 molecule-' s-' has been obtaine

Flash photolysis/time-resolved UV absorption measurements of the rate constants for the title reactions are reported over the temperature range 2 lo-253 K. The photolysis of F2/CF,H/03/02/N, gas mixtures reveals that the formation of CF302 and CF,O radicals has no measurable effect on the ozone conc

The rate constant for the reaction of O(") with H202 was measured as a function of temperature and the [H202]0/[0]0 ratio. The numerical solution of the appropriate rate equations was used to arrive a t a mechanism which adequately describes our results and the rather divergent data in the literatur

A method is proposed for studying the influence of vibrational excilation of radicals on their reactivity in bimolecular reactions. Investigations of the reaction CFZCI + HCI 4 CF2 HCI + Cl by this method show for the first time that this rexlion isaccelcrated by vibrational cscitntion of CFzCI\* ra