New insight into catechol photochemistry: the role of different monomer and dimer configurations in radiation-less decay of the S

The equilibrium geometries of the ground and first electronic excited states as well as the radiation-less deactivation channels of catechol in its monomer and dimer configurations were investigated using the standard linear-response and the spin-flipped TDDFT, multireference CASSCF as well as the similarity transformed equation-of-motion coupled cluster built with the domain-based local pair natural orbitals (DLPNO-STEOM-CCSD) methods. For the monomer, it was found that there is a new conical intersection geometry that can explain why catechol exhibits different photochemical behavior. This deactivation pathway involves almost simultaneously, an excited state intramolecular proton transfer between the two O atoms and an O-H bond breaks at the proton that is not between the two O atoms. From an energy balance point of view, these geometries are not associated with high potential barriers, so radiation-less relaxation can be achieved through these geometries. For the cyclohexane solvent, the lowest CI geometry shows an energy gap of about 4 kcal mol