Journal of Physical Chemistry A, Vol.110, No.28, 8605-8612, 2006
Ultrafast spectroscopy of free-base N-confused tetraphenylporphyrins
The photophysical characterization of the two tautomers ( 1e and 1i) of 5,10,15,20-tetraphenyl N-confused free-base porphyrin, as well as the tautomer-locked 2-methyl 5,10,15,20-tetraphenyl N-confused free- base porphyrin, was carried out using a combination of steady state and time-resolved optical techniques. N-Confused porphyrins, alternatively called 2-aza-21-carba-porphyrins or inverted porphyrins, are of great interest for their potential as building blocks in assemblies designed for artificial photosynthesis, and understanding their excited-state properties is paramount to future studies in multicomponent arrays. Femtosecond resolved transient absorption experiments reveal spectra that are similar to those of tetraphenylporphyrin ( H2TPP) with either Soret or Q-band excitation, with an extinction coefficient for the major absorbing band of 1e that was about a factor of 5 larger than that of H2TPP. The lifetime of the S-1 state was determined at a variety of absorption wavelengths for each compound and was found to be consistent with time-resolved fluorescence experiments. These experiments reveal that the externally protonated tautomer ( 1e) is longer lived ( tau = 1.84 ns) than the internally protonated form ( 1i, Y) 1.47 ns) by similar to 369 ps and that the N-methyl N-confused porphyrin was shorter lived than the tautomeric forms by similar to 317 ps ( DMAc) and similar to 396 ps ( benzene). Steady-state fluorescence experiments on tautomers 1e and 1i and the N-methyl analogues corroborate these results, with fluorescence quantum yields ( Phi(FI)) of 0.046 ( 1e, DMAc) and 0.023 ( 1i, benzene), and 0.025 ( DMAc) and 0.018 ( benzene) for the N-methyl N-confused porphyrin. The lifetime and quantum yield data was interpreted in terms of structural changes that influence the rate of internal conversion. The absorption and transient absorption spectra of these porphyrins were also examined in the context of DFT calculations at the B3LYP/6-31G( d)//B3LYP/3-21G( d) level of theory and compared to the spectra/electronic structure of H2TPP and tetraphenyl chlorin.