Structural Characterization Of The No(X-2 Pi)-N2o Complex With Mid-Infrared Laser Absorption Spectroscopy And Quantum Chemical Calculations

Both positive and negative ions of N3O2 have been observed in various experiments. The neutral N3O2 was predicted to exist either as a weakly bound NO.N2O complex or a covalent molecule. The rovibrational spectrum of the NO(X-2 Pi)-N2O complex has been measured for the first time in the 5.3 mu m region using distributed quantum cascade lasers to probe the direct absorption in a slit-jet supersonic expansion. The observed spectrum is analyzed with a semi-rigid asymmetric rotor Hamiltonian for a planar open-shell complex, giving a bent geometry with an a-axis-NO angle of about 21.9 degrees. The vibrationally averaged (2)A '-(2)A '' energy separation is determined to be epsilon = 144.56(95) cm(-1) for the ground state, indicating that the electronic orbital angular momentum is partially quenched upon complexation. Geometry optimizations of the complex restricted to a planar configuration at the RCCSD(T)/aug-cc-pVTZ level of theory show that the (2)A '' state is more stable than the (2)A ' state by about 110 cm(-1) and the N atom of NO points to the central N atom of N2O at the minimum of the (2)A '' state.