The internal state distribution of CN radicals produced in the photolysis of HC2CN and CH3CN

The energy partitioning in CN radicals produced by the vacuum ultraviolet photodissociation of HC2CN and CH3CN is studied by means of laser-induced fluorescence of the B-X transition. Experiments are performed in two collision regimes: (1) in the low-collision number regime, the energy partitioning in CN(X) is measured; (2) in the high-collision number regime, the formation of CN(A) is monitored. It is shown that photodissociation of HC2CN in its linear predissociative 1Sigma(+) state produces predominantly ground-state CN in rotationally and vibrationally excited states. The vibrational population ratios and the temperatures computed from a Boltzmann fit of the rotational levels are given in a table. The excitation of CH3CN produces CN radicals almost entirely in the first excited A-state with vibrational excitation.