Cobalt catalysis oxidation

Cobalt in Catalysis. Over 40% of the cobalt in nonmetaUic appHcations is used in catalysis. About 80% of those catalysts are employed in three areas (/) hydrotreating/desulfurization in combination with molybdenum for the oil and gas industry (see Sulfurremoval and recovery) (2) homogeneous catalysts used in the production of terphthaUc acid or dimethylterphthalate (see Phthalic acid and otherbenzene polycarboxylic acids) and (i) the high pressure oxo process for the production of aldehydes (qv) and alcohols (see Alcohols, higher aliphatic Alcohols, polyhydric). There are also several smaller scale uses of cobalt as oxidation and polymerization catalysts (44—46). 

Oxidation catalysts are either metals that chemisorb oxygen readily, such as platinum or silver, or transition metal oxides that are able to give and take oxygen by reason of their having several possible oxidation states. Ethylene oxide is formed with silver, ammonia is oxidized with platinum, and silver or copper in the form of metal screens catalyze the oxidation of methanol to formaldehyde. Cobalt catalysis is used in the following oxidations butane to acetic acid and to butyl-hydroperoxide, cyclohexane to cyclohexylperoxide, acetaldehyde to acetic acid and toluene to benzoic acid. PdCh-CuCb is used for many liquid-phase oxidations and V9O5 combinations for many vapor-phase oxidations. 

Alkanes, selective oxidation, cobalt catalysis, 44 291 Alkene... 

Hakkarainen, R. and Salmi, T. Water-gas shift reaction on a cobalt-molybdenum oxide catalyst. Applied Catalysis. A, General, 1993, 99, 195. 

Hutchings, G.J., Copperthwaite, R.G., Gottschalk, F.M., Hunter, R., Mellor, J., Orchard, S.W., and Sangiorgio, T. A comparative evaluation of cobalt chromium oxide, cobalt manganese oxide, and copper manganese oxide as catalysts for the water-gas shift reaction. Journal of Catalysis, 1992, 137, 408. 

Oxo reaction. A U.S. patent filed in 1938 by the German Otto Roelen and issued in 1943 disclosed the addition to an olefin of carbon monoxide and hydrogen under catalysis by cobalt, thorium oxide, or kieselguhr. The reaction was at first described as an oxo synthesis, but after Adkins and Krsek had examined the... 

For example, access to axial chirality can be realized under cobalt catalysis using a chiral cobalt(I) complex [4], However, the use of chiral iridium and rhodium species dramatically improved the scope and enantioselectivities obtained for this cycloaddition. Tanaka and coworkers synthesized an atropoisomeric diphosphine oxide in 97% ee, by treatment of the suitable hexayne with [Rh(cod)2]BF4 in the presence of (7 )-TolBINAP as source of chirality (double [2-1-2-1-2] cycloaddition). Subsequent reduction afforded an axially chiral bidentate ligand as a single enantiomer (Scheme 7.1) [5]. 

An early contribution to use of the transition-metal-catalyzed pyridine formation reaction was the synthesis of vitamin Be (124) via the crossed-cyclotrimerization reaction of the bis-stannylated diyne 122 with acetonitrile under cobalt catalysis (Scheme 7.26) [36a andb]. The underlying crossed [2 - - 2 - - 2] cycloaddition reaction here provided the fused pyridine 123 in 76% yield after a regioselective destannylation effected by treatment of the cycloaddition product with aluminum oxide. 

Nevertheless, the application of alkoxy-functionalized 1,3-dienes is of increasing interest. 1-Alkoxy-functionalized 1,3-butadienes led directly to arene derivatives such as 22 via the cycloaddition/elimination route (Scheme 13.12) [13]. The arene is formed under the reaction conditions of cobalt catalysis upon elimination of trimethyl-silanol from the labile dihydroaromatic intermediate. When 2-alkoxy-functionalized 1,3-butadienes are employed, 3,4-disubstituted phenol derivatives such as 23 are readily available by DDQ oxidation of the dihydroaromatic intermediate. The DDQ oxidation conditions led in several cases to direct desilylation of the enol ether or the desilylation takes place during column chromatography on (nondeactivated) silica gel. 

Grigorjeva and Daugulis further extended the scope of the cobalt catalysis of 8-aminoquinoline benzamide to achieve oxidative carbonylation... 

A. A. Mirzaei, M. Faizi, and R. Habibpour, Effect of preparation conditions on the catalytic performance of cobalt manganese oxide catalysts for conversion of synthesis gas to light olefins, Applied Catalysis A, vol. 306, pp. 98—107, 2006. 

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