Exploring energetic, structural and kinetic aspects of chemical species using highly correlated approaches

In this study, the structures, energies and vibrational frequencies for the X 3Σ- e A3II electronic states of CNN, and X 2II of the ions CNN+ and CNN- were obtained at the CCSD(T)/CBST-5 level of theory. Additionally, we also estimated the heats of formation for the neutral species ΔHf (0 K) = 138.89 kcal/mol and ΔHf(298.15 K) = 139.65 kcal/mol. For the ionization potential and electron affinities, this work predicted the values of 10.969 e 1.743 eV, respectively. Geometry optimizations for the electronic states 3Σ-, A 3II, a 1Δ, b 1Σ+, c 1II, d X 1Σ- e B 3Σ- performed with the MRCI approach allowed us to compute the excitation energies (Te). Furthermore, vertical transition energies were also calculated for 15 electronic states. Using the CCSD(T)-F12b/CBSD-Q level of theory, equilibrium geometries, and harmonic and anharmonic vibrational frequencies were estimated for the C3O molecule and the anion C3O-. An assessment of the effects of inclusion of core electrons in the calculation of some properties was also carried out. The determination of the heat of formation of the molecule C3O (ΔHf (0 K) = 79.41 kcal/mol and ΔHf (298.15 K) = 83.39 kcal/mol), and its electron affinity (1,114 eV) were the first ones reported in the literature. In the kinetics investigation, we estimated the rate constants for two hydrogen abstraction reactions. Rate constants for the reaction S(3P) + CH4 → SH + CH3 were predicted for a wide range of temperatures (T = 200 - 3000 K) using VTST/MT combined with DFT/M05-2X/MG3S calculations. At 1200 K, the calculated rate constant CVT/SCT for this process is 2.85 x 10-14 cm3 molecule-1 s-1. For the reaction of hydrogen abstraction from methyl butanoate by a hydrogen atom, the MS-VTST/MT method combined with the density functional MPWB1K/G-31+G(d,p) was employed. In this study, anharmonic torsional hindered rotations were considered in calculations of the rate constants. At high temperatures, the inclusion of torsional anharmonicity increases the rate constants by approximately 8-10%. At low temperatures, tunneling effects are predominant and the rate constant CVT/SCT (6.17 x 10-18 cm3 molécula-1 s-1) is 8.2 times higher than the CVT one (5.07 x 10-17 cm3 molécula-1 s-1 ). (AU)