Quantitative Analysis
of Intramolecular Exciplex and
Electron Transfer in a Double-Linked Zinc Porphyrin–Fullerene
Dyad
- Publication date
- Publisher
Abstract
Photoinduced charge transfer in a double-linked zinc
porphyrin–fullerene
dyad is studied. When the dyad is excited at the absorption band of
the charge-transfer complex (780 nm), an intramolecular exciplex is
formed, followed by the complete charge separated (CCS) state. By
analyzing the results obtained from time-resolved transient absorption
and emission decay measurements in a range of solvents with different
polarities, we derived a dependence between the observable lifetimes
and internal parameters controlling the reaction rate constants based
on the semiquantum Marcus electron-transfer theory. The critical value
of the solvent polarity was found to be ε<sub>r</sub> ≈
6.5: in solvents with higher dielectric constants, the energy of the
CCS state is lower than that of the exciplex and the relaxation takes
place via the CCS state predominantly, whereas in solvents with lower
polarities the energy of the CCS state is higher and the exciplex
relaxes directly to the ground state. In solvents with moderate polarities
the exciplex and the CCS state are in equilibrium and cannot be separated
spectroscopically. The degree of the charge shift in the exciplex
relative to that in the CCS state was estimated to be 0.55 ±
0.02. The electronic coupling matrix elements for the charge recombination
process and for the direct relaxation of the exciplex to the ground
state were found to be 0.012 ± 0.001 and 0.245 ± 0.022 eV,
respectively