Modulation of the proton transfer rate by excitation photons

Abstract

The effect of the exciting photon energy on the excited state proton transfer in a dye with dual fluorescence—FET (4′-diethylamino)-3-hydroxyflavone)—is studied. The steady-state fluorescence spectra are studied upon selective excitation by photons with different energies in the region of the main absorption band, as well as at its long-wavelength wing, in the temperature range of 2–30°C. It is found that, at all temperatures, the ratio of the integral emission of the normal and tautomeric forms, which are observed at 480 and 570 nm, respectively, depends on the excitation wavelength; namely, this ratio noticeably decreases with increasing excitation wavelength in the region of the main absorption band and its long-wavelength wing at 390–440 nm, and the rate of this decrease depends on temperature. In the same region, the long-wavelength excitation effect, which is atypical for inviscid solvents at room temperature, is observed; i.e., a short-wavelength emission band is bathochromically shifted by 6–15 nm depending on temperature. This spectral shift is directly related to the inhomogeneous broadening of the electronic spectra of the normal FET form, which is very large due to a considerable (>10 D) difference in the dye dipole moments. Most probably, the excitation creates the possibility of emission from nonrelaxed nonequilibrium orientational sublevels because their lifetime becomes shorter due to the proton transfer reaction, the rate of which in acetonitrile is comparable with the rate of intermolecular orientational relaxation. It is proposed to explain these dependences using energy diagram taking into account the dependence of the free energy on the orientational polarization of the solvent.