Direct chemical dynamics simulations of CN− + CH3I bimolecular nucleophilic substitution reaction

Abstract

Bimolecular nucleophilic substitution reactions have been studied for more than a century. Experimental and theoretical investigations of these reactions are extensively going on due to their wide applicability and the discovery of new features of these reactions. The CN⁻ + CH₃I nucleophilic substitution reaction can result in two isomeric products (NCCH₃/CNCH₃ + I⁻) because the incoming nucleophile has two reactive centers. Velocity map imaging experiments of this reaction have been reported and dominant direct rebound dynamics and high internal energy excitation of the reaction products were found in the experiments. However, it was not possible to directly obtain the isomer branching ratios from the experimental data and statistical ratios were predicted based on a numerical simulation. In the present work, direct chemical dynamics simulations of this reaction were performed using density functional theory and semi-empirical potential energy surfaces. Reactivity was low at all collision energies and direct rebound dynamics was observed in a major fraction of trajectories in agreement with experiments. However, the branching ratios computed from the trajectories were different from the previously reported estimates. Product energy distributions and scattering angles were computed and detailed atomic level reaction mechanisms are presented.