posted on 2013-02-15, 00:00authored byAshley
D. Bromby, Ryan P. Jansonius, Todd C. Sutherland
Core-modified 21,23-dithiaporphyrins, meso-substituted
with both electron-withdrawing 4-phenylcarboxylic acids and related
butyl esters, and electron-donating phenyldodecyl ethers were synthesized.
The porphyrins displayed broad absorbance profiles that spanned from
400 to 800 nm with molar absorptivities ranging from 2500 to 200000
M–1 cm–1. Electrochemical experiments
showed the dithiaporphyrins undergo two consecutive, one-electron,
quasi-reversible oxidations and reductions at −1.78, −1.43,
0.63, and 0.91 V versus a ferrocene/ferrocenium internal standard.
Spectroelectrochemistry and cyclic voltammetry revealed the dithiaporphyrins
are stable and can endure many cycles of oxidation and reduction without
signs of decomposition. The electronics of the two dithiaporphyrins
were similar, and DFT calculations showed the HOMO–LUMO energy
difference was smaller than tetrapyrrolic porphyrin analogues. Overall,
the combination of desirable electronics, namely: quasi-reversible
oxidations and reductions as well as broad absorbance profiles, combined
with stability, imply that these core-modified 21,23-dithiaporphyirns
could be potentially used as an ambipolar material for organic electronic
applications.