Litcius/Paper detail

Carboxylate breaks the arene C–H bond <i>via</i> a hydrogen-atom-transfer mechanism in electrochemical cobalt catalysis

Xinran Chen, Shuo‐Qing Zhang, Tjark H. Meyer, Chun-Hui Yang, Qin-Hao Zhang, Ji‐Ren Liu, Hua‐Jian Xu, Fahe Cao, Lutz Ackermann, Xin Hong

2020Chemical Science23 citationsDOIOpen Access PDF

Abstract

Combined computational and experimental studies elucidated the distinctive mechanistic features of electrochemical cobalt-catalyzed C-H oxygenation. A sequential electrochemical-chemical (EC) process was identified for the formation of an amidylcobalt(iii) intermediate. The synthesis, characterization, cyclic voltammetry studies, and stoichiometric reactions of the related amidylcobalt(iii) intermediate suggested that a second on-cycle electro-oxidation occurs on the amidylcobalt(iii) species, which leads to a formal Co(iv) intermediate. This amidylcobalt(iv) intermediate is essentially a cobalt(iii) complex with one additional single electron distributed on the coordinating heteroatoms. The radical nature of the coordinating pivalate allows the formal Co(iv) intermediate to undergo a novel carboxylate-assisted HAT mechanism to cleave the arene C-H bond, and a CMD mechanism could be excluded for a Co(iii/i) catalytic scenario. The mechanistic understanding of electrochemical cobalt-catalyzed C-H bond activation highlights the multi-tasking electro-oxidation and the underexplored reaction channels in electrochemical transition metal catalysis.

Topics & Concepts

ElectrochemistryCobaltCarboxylateCatalysisChemistryHydrogen atomHydrogen bondAtom (system on chip)PhotochemistryStereochemistryMoleculeInorganic chemistryPhysical chemistryOrganic chemistryGroup (periodic table)ElectrodeComputer scienceEmbedded systemCatalytic C–H Functionalization MethodsRadical Photochemical ReactionsSynthesis and Catalytic Reactions