Abstract
The lifetime of the lowest excited singlet (S(1)) state of peridinin and many other carbonyl-containing carotenoids and polyenes has been reported to depend on the polarity of the solvent. This effect has been attributed to the presence of an intramolecular charge transfer (ICT) state in the manifold of excited states for these molecules. The nature of this ICT state has yet to be elucidated. In the present work, steady-state and ultrafast time-resolved optical spectroscopy have been performed on peridinin and three synthetic analogues, C(33)-peridinin, C(35)-peridinin, and C(39)-peridinin, which have different numbers of conjugated carbon-carbon double bonds. Otherwise, the molecules are structurally similar in that they possess the same functional groups. The trends in the positions of the steady-state and transient spectral profiles for this systematic series of molecules allow an assignment of the spectral features to transitions involving the S(0), S(1), S(2), and ICT states. A kinetics analysis reveals the lifetimes of the excited states and the dynamics of their excited state deactivation pathways. The most striking observation in the data is that the lifetime of the ICT state converges to the same value of 10.0 +/- 2.0 ps in the polar solvent, methanol, for all the peridinin analogues, regardless of the extent of pi-electron conjugation. This suggests that the ICT state is highly localized on the lactone ring, which is a common structural feature in all the molecules. The data further suggest that the S(1) and ICT states behave independently and that the ICT state is populated from both S(1) and S(2), the rate and efficiency from S(1) being dependent on the length of the pi-electron chain of the carotenoid and the solvent polarity.