ABSTRACT
The iron(III)-catalyzed oxidative coupling of diarylamines to 2,2'-bis(arylamino)-1,1'-biaryls and subsequent twofold palladium(II)-catalyzed oxidative cyclization provide a convergent synthetic route to 1,1'-bicarbazoles. Screening a range of different palladium(II) salts led to palladium(II) acetate, pivalate, and hexafluoroacetylacetonate as the most efficient catalysts. Remarkably, the twofold palladium(II)-catalyzed oxidative cyclization can also be performed under argon. The mechanism for the oxidative cyclization under an inert gas presumably involves regeneration of the catalytically active palladium(II) species by oxidative addition of pivalic acid.
ABSTRACT
The diverse mechanisms for the reductive elimination of biaryl compounds from diarylpalladium(II) complexes with a tetradentate ligand were investigated through a combined experimental and computational study. At least four distinct chemical triggers with specific regioselectivity exist for this elimination. Heating of the complexes in inert solvents (e.g., para-xylene) reveals their relatively high thermal stability as reflected by a very high barrier for a unimolecular reductive elimination. In contrast, electron-donor ligands like triphenylphosphine induce a facile reductive elimination via twofold associative ligand exchange as confirmed by kinetic experiments, which are in good agreement with the computational results. Oxidants, such as H2 O2 , can trigger an oxidation-induced reductive elimination via palladium(IV) intermediates at room temperature. Rearrangement of the diarylpalladium(II) complexes can occur in organic acids, facilitating a reductive elimination with distinct regiochemical outcome.
