The elusive active species in nickel()-mediated oxidations of hydrocarbons by peracids: a Ni-oxyl species, an aroyloxy radical, or a Ni-peracid complex?

Nonheme nickel( ii )-mediated oxidations of hydrocarbons by meta -chloroperbenzoic acid ( m CPBA) show promising activity and selectivity; however, the active species and the reaction mechanism of these reactions are still elusive after decades of efforts. Herein, a novel free radical chain mechanism of the Ni( ii )-mediated oxidation of cyclohexane by m CPBA is investigated using density functional theory calculations. In this study, we rule out the involvement of a long speculated Ni II -oxyl species. Instead, an aroyloxy radical ( m CBA&z.rad;) and a Ni III -hydroxyl species formed by a rate-limiting O-O homolysis of a Ni II - m CPBA complex are active species in the C-H bond activation to form a carbon-centered radical R&z.rad;, where m CBA&z.rad; is more robust than the Ni III -hydroxyl species. The nascent R&z.rad; radical either reacts with m CPBA to form a hydroxylated product and a m CBA&z.rad; radical to propagate the radical chain or reacts with the solvent dichloromethane to form a chlorinated product. In addition, the Ni II - m CPBA complex is found for the first time to be a robust oxidant in hydroxylation of cyclohexane, with an activation energy of 13.4 kcal mol −1 . These mechanistic findings support the free radical chain mechanism and enrich the mechanistic knowledge of metal-peracid oxidation systems containing transition metals after group 8 in periodic table of elements. A multiple-oxidant mechanism, in which a m CBA· radical, a Ni III -OH species and a Ni II - m CPBA complex act as the oxdiants, works in Ni( ii )-mediated oxidation of cyclohexane with m CPBA.