Structure Pairs of Pd(III) centers can couple, giving rise to a Pd–Pd
bond. In contrast to the mononuclear Pd(III) complexes, the Pd(III)-Pd(III)
dimers are diamagnetic. The first example of a dipalladium(III) complex was obtained by oxidation of dinuclear Pd(II) complex of
triazabicyclodecene. The first organometallic dinuclear Pd(III) complexes were reported in 2006 by Cotton and coworkers as well. These complexes catalyze the diborylation of terminal olefins. Due to the facile reduction of these complexes to Pd(II) species by diborane, the authors proposed that the dinuclear Pd(III) complexes serve as precatalysts for active Pd(II) catalysts. (Ph groups omitted for clarity).
Reactivity The reactivity of dinuclear Pd(III) species as active catalytic intermediate is mostly discussed in the context of
C-H activation. While it was proposed that Pd-catalyzed oxidative C-H functionalization reactions involve a Pd(IV) intermediate, Ritter and coworkers first postulated that these oxidative reactions could involve a dinuclear Pd(III) intermediate instead of Pd(IV). Dinuclear Pd species are involved in Pd-catalyzed C-H chlorination. Through X-ray crystallography, Ritter unambiguously showed that dinuclear Pd(III) complex is formed when the
palladacycle is treated with two-electron oxidant, and such dinuclear complex undergoes C-Cl reductive elimination under ambient temperature. Both experimental and computational data was consistent with a concerted 1,1-reductive elimination mechanism for the C-Cl forming step. The authors show that such bimetallic participation of redox event lowers the activation barrier for reductive elimination step by ~30 kcal/mol compared to a monometallic pathway.
Acetoxylation of
2-phenylpyridine was also demonstrated to involve a dinuclear Pd(III) intermediate. ==See also==