Next-Generation Quantum Theory of Atoms in Molecules for the Ground and Excited States of Fulvene

Abstract

A vector-based representation of the chemical bond is introduced that we refer to as the bond-path frame-work set = B = \p, q, r\, where p, q and r represent three paths with corresponding eigenvector-following path lengths H*,H and the familiar quantum theory of atoms in molecules (QTAIM) bond-path length. The eigenvector-following path lengths H* and H are constructed along the bond-path from the e1 and e2 Hessian eigenvectors respectively, which correspond to the least and most preferred directions of charge density accumulation. In particular, the paths p and q provide a vector representation of the scalar QTAIM ellipticity ε. The bond-path frame-work set B is applied to the excited state deactivation of fulvene that involves distortions along various intramolecular degrees of freedom, such as the bond stretching/compression of bond length alternation (BLA) and bond torsion distortions. We find that the H* and H lengths can differentiate between the ground and excited electronic states, in contrast to the QTAIM bond-path length. In particular, the eigenvector-following path lengths H* and H are found to be shorter for the excited state than the ground state for both the BLA and bond torsion distortions indicating that distortions resulting in lower H* and H values are easier to perform.