2-(6'-Hydroxy-2'-pyridyl)benzimidazole (BI), having double functional groups donating protons, is investigated theoretically with an aim to determine the excited-state proton transfer (ESPT) mechanism in different solvents. We demonstrate that the ESPT reaction can take place with the assistance of protic solvents (water and ethanol). At the same time, the vitally important role of bridges of water and ethanol for the ESPT reaction is confirmed by the disappearance of the ESPT reaction when we replaced the protic solvent with aprotic solvent acetonitrile (ACN). We regulate the ESPT reaction of BI via solvents successfully. A different ESPT mechanism from the one proposed previously (the proton of BI transfers from benzimidazole NH to pyridyl nitrogen in ethanol) is proposed. Our simulated potential energy barriers indicate that the ESPT reaction of BI can occur only between the hydroxyl proton and pyridyl nitrogen with the assistance of water or ethanol molecules. We further verify that the water- or ethanol-assisted ESPT reaction of BI is stepwise, and the concerted mechanism is unambiguously ruled out. This systematic investigation into the ESPT mechanism of BI is significant in designing and constructing the desirable supramolecular architectures, which can provide potential supramolecular recognition sites and supramolecular inter- or intra-H-bonding interactions.
Keywords: excited-state proton transfer; hydrogen bond; solvent effect; solvent-assisted proton transfer.