A Multireference Configuration Interaction Study of the Photodynamics of Nitroethylene

[Image: see text] Extended multireference configuration interaction with singles and doubles (MR-CISD) calculations of nitroethylene (H(2)C=CHNO(2)) were carried out to investigate the photodynamical deactivation paths to the ground state. The ground (S(0)) and the first five valence excited electronic states (S(1)–S(5)) were investigated. In the first step, vertical excitations and potential energy curves for CH(2) and NO(2) torsions and CH(2) out-of-plane bending starting from the ground state geometry were computed. Afterward, five conical intersections, one between each pair of adjacent states, were located. The vertical calculations mostly confirm the previous assignment of experimental spectrum and theoretical results using lower-level calculations. The conical intersections have as main features the torsion of the CH(2) moiety, different distortions of the NO(2) group and CC, CN, and NO bond stretchings. In these conical intersections, the NO(2) group plays an important role, also seen in excited state investigations of other nitro molecules. Based on the conical intersections found, a photochemical nonradiative deactivation process after a π–π* excitation to the bright S(5) state is proposed. In particular, the possibility of NO(2) release in the ground state, an important property in nitro explosives, was found to be possible.