The resulting optimized structure was of point symmetry D3, and the calculated Raman spectrum provided an excellent match with the observed normal Raman spectrum. This provided a reliable assignment of the symmetry and normal modes of the observed spectrum, which consists of bands assigned to modes of either a1 or e symmetry. The e modes were not split, showing that D3 symmetry remained, even on the surface. The SERS spectra, both normal and single-molecule, were dominated by the nontotally symmetric e vibrations, which were preferentially enhanced in accord with the Herzberg−Teller-surface selection rules. The mechanism involves intensity borrowing through vibronic coupling between a charge-transfer state and the lowest-lying π → π* transition. A quantitative measure of the degree of charge transfer was obtained by analyzing the potential dependence of SERS intensities. This indicates a considerable contribution of charge-transfer intensity to the overall SERS enhancement. (publisher abstract modified)