posted on 2015-02-12, 00:00authored byBogdan Dereka, Romain Letrun, Denis Svechkarev, Arnulf Rosspeintner, Eric Vauthey
The
electronic absorption spectrum of 3-hydroxyflavone (3HF) in
various solvents exhibits a long-wavelength (LW) band, whose origin
has been debated. The excited-state dynamics of neutral and basic
solutions of 3HF in alcohols upon excitation in this LW band has been
investigated using a combination of fluorescence up-conversion and
transient electronic and vibrational absorption spectroscopies. The
ensemble of results reveals that, in neutral solutions, LW excitation
results in the population of two excited species with similar fluorescence
spectra but very different lifetimes, namely 40–100 ps and
2–3 ns, depending on the solvent. In basic solutions, the relative
concentrations of these species change considerably in favor of that
with the short-lived excited state. On the basis of the spectroscopic
data and quantum chemistry calculations, the short lifetime is attributed
to the excited state of 3HF anion, whereas the long one is tentatively
assigned to an excited hydrogen-bonded complex with the solvent. Excited-state
intermolecular proton transfer from the solvent to the anion yielding
the tautomeric form of 3HF is not operative, as the excited anion
decays to the ground state via an efficient nonradiative transition.