Description of the Methylene Amidogene Radical and Its Anion with an Economical Treatment of Correlation Effects Using Density Functional Theory Orbitals

The ground and low-lying excited state electronic structural properties (such as equilibrium geometries, harmonic frequencies, excitation energies, barrier energy, and so on) of the methylene amidogene radical (H2CN) and its anion (H2CN-) have been studied using the CASCI (complete active space configuration interaction) and SSMRPT (state-specific multireference Moller-Plesset perturbation theory) methods with density function theory (DFT) orbitals. Here, the span of the active orbitals have been obtained from Kohn-Sham DFT using B3LYP exchange-correlation functionals in the CASCI (DFT-CASCI) approximation to describe nondynamic correlation associated with electronic degeneracies. The DFT-SSMRPT protocol provides an attractive way to deal with both dynamical and nondynamical correlation effects in strongly correlated systems such as H2CN and H2CN-. The present work clearly indicates that the electronic absorption band near 35,050 cm(-1) corresponds to the (B) over tilde (2) A(1) <- (X) over tilde B-2(2) transition. DFT-SSMRPT findings are in close agreement with high-level theoretical estimates. It is concluded that the transition at 1725 cm(-1) could be due to the CN stretching of the trans-HCNH isomer which is originally assigned to the CN stretch of H2CN in the experiment. The present results confirm most of the previous vibrational assignments. It is not possible to definitively assign a transition to the 35,600 cm(-1) band with the present estimations, suggesting further experiment is urgently called for.

Automated summary

The electronic structural properties of methylene amidogene radical (H2CN) and its anion have been studied using CASCI and SSMRPT methods with DFT orbitals. The study confirms the electronic absorption band near 35,050 cm(-1) and suggests further experiments for assignment of a transition to the 35,600 cm(-1) band. The results are in close agreement with high-level theoretical estimates and contribute to a better understanding of vibrational assignments.