Predicting Competitive and Non-Competitive Torquoselectivity in Ring-Opening Reactions using QTAIM and the Stress Tensor

Abstract

We present a new vector-based representation of the chemical bond referred 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 bond-path length from the quantum theory of atoms in molecules (QTAIM). We find that longer path lengths H of the ring-opening bonds predict the preference for the transition state inward (TSIC) or transition state outward (TSOC) ring opening reactions in agreement with experiment for all five reactions R1-R5. Competitiveness and non-competitiveness have traditionally been considered using activation energies. The activation energy however, for R3 does not satisfactorily determine competitiveness or provide consistent agreement with experimental yields. We choose a selection of five competitive and non-competitive reactions; methyl-cyclobutene (R1), ethyl-methyl-cyclobutene (R2), iso-propyl-methyl-cyclobutene (R3), ter-butyl-methyl-cyclobutene (R4) and phenyl-methyl-cyclobutene (R5). Therefore, in this investigation we provide a new criterion, within the QTAIM framework, to determine whether the reactions R1-R5 are competitive or non-competitive. We that find R2, R3 and R5 are competitive and R1 and R4 are non-competitive reactions in contrast to the results from the activation energies, calling into question the reliability of activation energies.