Theoretical insights from computational analyses: solvent-polarity-associated excited state behaviours for the novel NP-BSD chemosensor

Abstract

Given the potential luminous advantages of salicylideneaniline (SA) derivatives, in this work, the phenyl π-extension-bis(salicylidene)-1,5-diaminonaphthalene (NP-BSD) fluorophore is explored on its photo-induced reactional behaviours in solvents theoretically. Given solvent surroundings with different polarities, we studied the hydrogen-bonding interactions in different solvents and their influences on excited state proton transfer (ESPT) reaction by photoexcitation for NP-BSD fluorophore. First, photo-induced geometrical variations related to dual hydrogen bonds (O1-H2···N3 and O4-H5···N6) and infrared (IR) vibrational changes and qualitative chemical bond strength reveal excited-state hydrogen bonding enhancement. Probing into the photo-induced excitation process, the charge redistribution derived from vertical excitation confirms the tendency of ESIPT reaction for NP-BSD fluorophore. By constructing potential energy surfaces (PESs) in three aprotic polar solvents, the excited-state intramolecular double proton transfer (ESIDPT) mechanism of NP-BSD could be verified that could be regulated by solvent polarity. We clarify and present the solvent-polarity-associated ESIDPT behaviours for NP-BSD fluorophore.