15min:

MOHAMMED A. GHARAIBEH, DENNIS J. CLOUTHIER, Department of Chemistry, University of Kentucky, Lexington, KY 40506-0055.

Although the A² _i - X² _i band system of the chlorine cation has been known since 1928 and has been studied by many investigators, no satisfactory vibrational assignment has been achieved due to substantial vibronic perturbations. In the present work, laser-induced fluorescence and single vibronic level (SVL) emission spectra of the jet-cooled chlorine cation (Cl₂⁺) have been investigated in the region of 500-312 nm. The cation was produced in a pulsed electric discharge jet using a precursor mixture of 10% chlorine gas in high pressure argon. The spectrum has been extended further to the red than previously known and the 1-0 band has been identified. The 0-0 band was undetectable due to a very small Franck-Condon factor for this transition. Due to efficient cooling in the supersonic expansion, no hot bands and no transitions from the X² _1/2 spin-orbit component were observed in our coldest spectra. Chlorine isotope shifts and the number of nodes in the SVL emission spectra were used as diagnostics in assigning the vibrational quantum numbers. SVL emission spectra of ³⁵Cl₂⁺ terminated on levels up to v'' = 15 and these data were used to determine _e'' = 645.0(1) and _ex_e'' = 2.927(7) cm^-1. High resolution spectra of the 1-0 and 2-0 bands of ³⁵Cl₂⁺ and ³⁵Cl³⁷Cl⁺ have been recorded and rotationally analyzed, yielding r_e' = 2.2287(7) and r₀'' = 1.8944(3) Å.