AI Article Synopsis
- Researchers studied the anionic states of benzonitrile using advanced electronic structure methods and found that the ground state of the anion is the valence 2B1 state.
- The dipole-bound state exists about 0.1 eV above the valence state and plays a crucial role in the formation of the anion by acting as a gateway for capturing electrons.
- The findings indicate that electron capture occurs through the dipole-bound state, leading to subsequent relaxation that results in the stabilization of valence anions.
Article Abstract
Anionic states of benzonitrile are investigated by high-level electronic structure methods. The calculations using equation-of-motion coupled-cluster theory for electron-attached states confirm earlier conclusions drawn from the photodetachment experiments wherein the ground state of the anion is the valence 2B1 state, while the dipole bound state lies adiabatically ∼0.1 eV above. Inclusion of triple excitations and zero-point vibrational energies is important for recovering relative state correct ordering. The computed Franck-Condon factors and photodetachment cross-sections further confirm that the observed photodetachment spectrum originates from the valence anion. The valence anion is electronically bound at its equilibrium geometry, but it is metastable at the equilibrium geometry of the neutral. The dipole-bound state, which is the only bound anionic state at the neutral equilibrium geometry, may serve as a gateway state for capturing the electron. Thus, the emerging mechanistic picture entails electron capture via a dipole bound state, followed by non-adiabatic relaxation forming valence anions.
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| http://dx.doi.org/10.1039/c9cp06484b | DOI Listing |
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