Quenching of I (2P1/2) by halogen cyanides

The rate of CoLlisional quenching or I(5p' \*P ,,$ by I2 has been determined u&g time-resolved atomic absorption spectroscopy following tunable laser photoiysis of molecular iodine as (3.6 + 0.3) X 10-l' cm3 mole&k-' s-l. Disaepancies between this and earlier results are discussed.

A systematic study of the quenching of Ba( 'PI) fluorescence by CH4 in Ar clusters has been performed for different argon cluster sizes and numbers of methane molecules in the clusters. The quenching rate as a function of the number of methane molecules in a given cluster follows a first-order rate

AbStTWt A picosecond time-resolved study of the interaction of Br with Is is presented. The bromine atom is formed by photodissociation of the HBr in the van der Waals dimer HBrIs at 220 nm. The resultant molecular products are detected by picosecond REMPI. We see primarily vibrationally excited 1s

I\* emission. These have been extended to many systems to understand the mechanism involved in energy transfer processes. This problem has been tackled using several approaches: (a) Direct measurement of state-to-state E-v rate constants; (b) Temperature dependence of the bulk or overall quenching r

Rate constants for quenching of CH2 (6 'B, ) C( 0,14,0) by six hydrocarbons have been measured. 'B, methylene was prepared by a two-step process. In the first step ketene was photodissociated by a XeCl excimer laser yielding CH,(% 'A, ). Subsequently CH2( 'B, ) was populated by dye-laser absorption

Collisional deactivation of by the title compounds was investigated through 2 I( P ) 1/2 the use of the time-resolved atomic absorption of excited iodine atoms at Rate 206.2 nm. constants for atomic spin-orbit relaxation by CH 3 Cl, CH 2 Cl 2 , CHCl 3 , CCl 3 F, and CCl 4 are and Ϫ13 Ϫ13 Ϫ14 Ϫ15 3.