Photoinduced electron transfer reaction tuned by donor-acceptor pairs via the rigid, linear spacer heptacyclo[6.6.0.0.0.0.0.0]tetradecane

A new class of donor-{saturated hydrocarbon bridge}-acceptor (D-B-A) dyads were synthesized and utilized on a systematic approach to evaluate the corresponding photoinduced electron transfer (ET) process. Among these dyads heptacyclo6.6.0.0^2,6.0^3,13.0^4,11. 0^5,9.0^10,14]tetradecane (HCTD) was used as a unique spacer, which possesses a geometry of high symmetry (D_2d), rigidity and linearity. The spectroscopy and dynamics of excited-state ET as functions of donor/acceptor electronic states, orientation as well as solvent properties were analyzed with the aid of theoretical computations. It was observed that the quenching of donor fluorescence (the F₁ band) correlated with the appearance of a broad charge-transfer (CT) emission. Both wavelength and intensity of the CT band varied with solvent-polarity, whereas its rise dynamics complied well with the decay of the F₁ band. In acetonitrile, the CT state decays much faster than the rate of ET (∼63 ps⁻¹) so that the corresponding steady-state emission cannot be resolved. An intriguing effect was observed in the case of benzene-1,2-dithioketals (3a and 3b) where the D and A π-chromophores were aligned in different orientations. The estimated ET rate of 3a (3.9×10¹⁰ s⁻¹) was substantially faster than that of 3b (7×10⁸ s⁻¹). The experimental data were tentatively fitted by a semi-log plot of ET rate constants (k_et) against free energy (ΔG⁰), yielding a value of ∼17.3 cm⁻¹ for the electron-coupling matrix (H_el).