96109-48-7Relevant academic research and scientific papers
Cobalt(III) Alkylperoxy Complexes. Synthesis, X-ray Structure, and Role in the Catalytic Decomposition of Alkyl Hydroperoxides and in the Hydroxylation of Hydrocarbons.
Saussine, Lucien,Brazi, Eric,Robine, Alain,Mimoun, Hubert,Fischer, Jean,Weiss, Raymond
, p. 3534 - 3540 (1985)
Novel cobalt(III) alkylperoxy complexes with the general formula Co(R''BPI)(OCOR')(OOR) and Co(BPB)(OOt-Bu)(4-Mepy) were synthesized from the reaction of alkyl hydroperoxides with their Co(II) precusor, and characterized by physicochemical methods.The X-ray structure of Ib (R'' = H, R' = Ph, R = t-Bu) revealed a distorted octahedral environment with a chelating carboxylate moiety and an apically bonded tert-butylperoxy group.The reactivity of cobalt(III) alkylperoxy complexes toward hydrocarbons was found to be dependent on their thermal decomposition rate, with type I complexes being the most reactive ones.Saturated hydrocarbons are oxidized by Co(III) tert-butylperoxy complexes into alcohols, ketones, and tert-butylperoxy products.The hydroxylation reaction preferentally occurs at the more nucleophilic C-H bonds with extensive epimerization at the hydroxylated carbon atom.Hydrocarbons having labile allylic or benzylic C-H bonds react beginning at room temperature to give a large amount of allylic or benzylic tert-butyl peroxide.Olefins having no allylic hydrogen atom are preferentially transformed into epoxides.The catalytic hydroxylation of alkanes by t-BuOOH in the presence of complexes I-III has the same characteristics as the stoichiometric reaction.The homolytic decomposition and reactivity of cobalt(III) alkylperoxy complexes is discussed in the context of the Haber-Weiss mechanism of alkyl hydroperoxide decomposition and of hydrocarbon hydroxylation by first-row transition-metal peroxides.
Catalytic conversion of cyclohexylhydroperoxide to cyclohexanone and cyclohexanol
Tolman, C. A.,Druliner, J. D.,Krusic, P. J.,Nappa, M. J.,Seidel, W. C.,et al.
, p. 129 - 148 (1988)
The low-conversion air oxidation of cyclohexane yields a mixture of cyclohexylhydroperoxide, cyclohexanone and cyclohexanol. The cyclohexyl-hydroperoxide is converted to additional cyclohexanone and cyclohexanol before the mixture is concentrated. Cobalt octoate is an active but short-lived catalyst for this transformation. Using a combination of pulse calorimetry and chemical luminescence techniques, a new family of long-lived catalysts has been discovered. These catalysts, based upon the (bis(2-pyridylimino)isoindolinato) ligand, are very active and long-lived, allowing cyclohexylhydroperoxide to be converted in a selective, low temperature process.
