Copper catalyzed aerobic reaction mechanism

We have shown, in stoichiometric experiments, that reaction of copper(I) with TEMPO affords a piperidinyloxyl copper(II) complex. Reaction of the latter with a molecule of alcohol afforded the alkoxycopper(II) complex and TEMPOH. Reaction of the alkoxycopper(II) complex with a second molecule of TEMPO gave the carbonyl compound, copper(I), and TEMPOH. This mechanism resembles that proposed for the aerobic oxidation of alcohols catalyzed by the copper-dependent enzyme, galactose oxidase, and mimics thereof. Finally, TEMPOH is reoxidized to TEMPO by oxygen. We have also shown that copper in combination with PIPO affords an active and recyclable catalyst for alcohol oxidation [18]. 

SemmeUiack et al. [104] reported that the combination of CuCl and 4-hydroxy TEMPO catalyzes the aerobic oxidation of alcohols. However, the scope was limited to active benzyhc and allylic alcohols and activities were low (10 mol% of catalyst was needed for smooth reaction). They proposed that the copper catalyzes the reoxidation of TEMPO to the oxoammonium cation. Based on our results with the Ru/TEMPO system we doubted the validity of this mechanism. Hence, we subjected the Cu/ TEMPO to the same mechanistic studies described above for the Ru/TEMPO system [105]. The results of stoichiometric experiments under anaerobic conditions, Hammett correlations and kinetic isotope effect studies showed a similar pattern to those with the Ru/TEMPO system, i.e., they are inconsistent with a mechanism involving an oxoammonium species as the active oxidant. Hence, we propose the mechanism shown in Scheme 4.18 for Cu /TEM PO-catalyzed aerobic oxidation of alcohols. 

Nonstereospecific aerobic epoxidations of alkenes in the presence of aldehydes catalyzed by nickel(II),298 iron(in),299 and cobalt(II)300 complexes, and clay-supported nickel acetylacetonate301,302 have been reported. A radical mechanism has been postulated. The involvement of active copper species and peracids were suggested in a similar reaction catalyzed by copper salts.303... 

Cytochrome c oxidase (COX) is the terminal enzyme in the respiratory system of most aerobic organisms and catalyzes the four electron transfer from c-type cytochromes to dioxygen (115, 116). The A-type COX enzyme has three different redox-active metal centers A mixed-valence copper pair forming the so-called Cua center, a low-spin heme-a site, and a binuclear center formed by heme-fl3 and Cub. The Cua functions as the primary electron acceptor, from which electrons are transferred via heme-a to the heme-fl3/CuB center, where O2 is reduced to water. In the B-type COX heme-u is replaced by a heme-fo center. The intramolecular electron-transfer reactions are coupled to proton translocation across the membrane in which the enzyme resides (117-123) by a mechanism that is under active investigation (119, 124—126). The resulting electrochemical proton gradient is used by ATP synthase to generate ATP. 

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