A four-dimensional potential energy surface for the He - HCN complex

Abstract

A four-dimensional potential energy surface for the interaction between He and HCN with vibrational bending is presented. Ab initio calculations were carried out at the coupled-cluster level with single and double excitations and a perturbative treatment of triple excitations, using a quadruple-zeta basis set and mid-bond functions. An accurate fit to the Ab-initio data has been obtained with a parametrized functional form. The global minimum is found in the linear He-HCN configuration with the H atom pointing towards Helium at the intermolecular separation of 7.94 a0. The corresponding well depth is 30.35 cm-1 . The quality of the new potential has been tested by performing two comparisons with previous theoretical and experimental works. First, the rovibrational energy levels of the He-HCN complex for a linear configuration of the HCN molecule have been calculated. The dissociation energy is 8.99 cm-1, which is slightly smaller than the semi-empirical value of 9.42 cm-1 . The transitions frequencies are found to be in good agreement with the experimental data. Second, we performed close coupling calculations of the rotational de-excitation of HCN in collisions with He and observed a close similarity with the theoretical data published in a recent study.