Single collision ion–molecule reactions at thermal energy: Rotational and vibrational distributions from N++CO→N+CO+

Abstract

A new apparatus is developed and used to obtain nascent vibrational and rotational distributions in the ground electronic state of CO⁺ formed from the charge transfer reaction N⁺(³P)+CO (X ¹Σ⁺)→N(⁴S)+CO⁺ (X ²Σ⁺,v,J)+0.52 eV, at approximately thermal energies. The device utilizes a flow tube for the production of thermal N⁺ ions in a helium buffer and a large diameter sampling orifice which delivers the ions via a mild free jet expansion into a low pressure chamber. The expansion is crossed by a stream of reactant CO molecules and the CO⁺ product states are probed by laser‐induced fluorescence. Although the energy available is sufficient to populate CO⁺ vibrational states up to v″=2, the major vibrational channel in the CO⁺ product is v″=0. The relative vibrational distribution is found to be: N_v=0≳0.81 (observed under single collision conditions), N_v=1N_v=2≊0.04 (observed only under nonsingle collision conditions). The rotational distribution in the v″=0 state is characterized closely by a Boltzmann distribution with a temperature of 410±50 K. This represents a fractional energy disposal into rotation of only 2%. Nearly all of the reaction exothermicity is therefore released into translational recoil. These results are considered in terms of simple dynamical models of the charge transfer process.