Quinones are important oxidants in biology and synthetic chemistry. Herein, we study the kinetics of the oxidation of hydroquinones to quinones with redox-active guanidines and thioguanidines. In the first section, we report the synthesis and characterization of the first redox-active aromatic compounds with two, three, and four thioguanidino groups and compare their redox properties with the corresponding oligoguanidines. The stable salts obtained upon chemical two-electron oxidation of the tetra-thioguanidine were then applied in dehydrogenative P-P coupling reactions at room temperature, demonstrating their superior proton-coupled electron-transfer reactivity compared with previously used oligoguanidines. Oxidation of hydroquinones and halogenated derivatives to the 1,4-benzoquinones is also much faster with the new tetrathioguanidine than with oligoguanidines. Seemingly paradoxically, for tetraguanidines and tetrathioguanidines, oxidations to high-potential halogenated quinones are faster than those to low-potential quinones (due to proton-coupled electron transfer (PCET)), motivating the use of redox-active guanidines as redox mediators.
Wild et al. (Fri,) studied this question.