Time resolved resonance fluorescence study of electronically excited iodine atoms, I(52P1/2)

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.

Recawd /3-hIay 1980. III find form 1-8 May 1980 The direct obserratton of S(3 'Dz) using tlmc-rcsolred resonance fluorescence IS reported Rate data for the removal of thus cwatcd state by C& OCS and CH.1 arc presented, and compared ~1t.h data obtamed usmg absorption techniques S(3 'Dz) WIS produced

A method is described for the phot~le~c me~~ment of the time-resolved atomic absorption by electronically excited iodine atoms, 1(5'Prn), generated by pulsed irradiation-A kinetic investigation of the decay of these excited atoms yields a vaIlle for the quenching rate constant by mo?ecuku oxygen, th

Eiectronicalfy excited carbon atoms in the lowest lying singtet state, C(Zf13.$ ~ have been monitored directly by photoelectric measurement of the attenuation of the resonance transition C(VYI~P\* -2lD2) at 193.1 nm. The rate of decay of Lhe atom has been measured in the presence of hydrogen an fd n

A kinetic investigation of electronically excited arsenic atoms in the low-lying states, As(4ps ' 0 5 ) and As(4p3 2P~), ca. 1.33 and 2.28 eV, respectively, above the 44S312 ground state, has been carried out by atomic absorption spectroscopy. Atoms in these optically metastable states were generate