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Anodic oxidation Kolbe coupling processes

Faraday, in 1834, was the first to encounter Kolbe-electrolysis, when he studied the electrolysis of an aqueous acetate solution [1], However, it was Kolbe, in 1849, who recognized the reaction and applied it to the synthesis of a number of hydrocarbons [2]. Thereby the name of the reaction originated. Later on Wurtz demonstrated that unsymmetrical coupling products could be prepared by coelectrolysis of two different alkanoates [3]. Difficulties in the coupling of dicarboxylic acids were overcome by Crum-Brown and Walker, when they electrolysed the half esters of the diacids instead [4]. This way a simple route to useful long chain l,n-dicarboxylic acids was developed. In some cases the Kolbe dimerization failed and alkenes, alcohols or esters became the main products. The formation of alcohols by anodic oxidation of carboxylates in water was called the Hofer-Moest reaction [5]. Further applications and limitations were afterwards foimd by Fichter [6]. Weedon extensively applied the Kolbe reaction to the synthesis of rare fatty acids and similar natural products [7]. Later on key features of the mechanism were worked out by Eberson [8] and Utley [9] from the point of view of organic chemists and by Conway [10] from the point of view of a physical chemist. In Germany [11], Russia [12], and Japan [13] Kolbe electrolysis of adipic halfesters has been scaled up to a technical process. [Pg.92]

Anodic oxidation of a-cyanocarboxylates generates a delocalised radical. Dimerization occurs by both carbon-carbon and carbon-nittogen coupling [79], Oxidation of p-ketocarboxylates using a platinum anode and a mercury pool cafliode, to prevent the solution becoming alkaline, causes the dimerization process. The alternative non-Kolbe process, giving an a,P-unsaturated ketone, is followed when die solution is strongly alkaline [80]. [Pg.317]

Electron donating a-substituents favour the non-Kolbe reaction but the radical intermediates in these anodic processes can be trapped during co-electrolysis with an alkanoic acid. Anodic decarboxylation of sugar uronic acids leads to formation of the radical which is very rapidly oxidised to a carbonium ion, stabilised by the adjacent ether group. However, in the presence of a tenfold excess of an alkanoic acid, the radical intermediate is trapped as the unsymmetrical coupling product [101]. Highly functionalised nucleotide derivatives such as 20 will couple successfully in the mixed Kolbe reaction [102], Other examples include the co-electrolysis of 3-oxa-alkanoic acids with an alkanoic acid [103] and the formation of 3-alkylindoles from indole-3-propanoic acid [104], Anodic oxidation of indole-3-propanoic acid alone gives no Kolbe dimer [105],... [Pg.321]


See other pages where Anodic oxidation Kolbe coupling processes is mentioned: [Pg.105]    [Pg.58]    [Pg.911]    [Pg.58]    [Pg.193]    [Pg.98]    [Pg.1443]    [Pg.338]    [Pg.1353]    [Pg.474]   
See also in sourсe #XX -- [ Pg.86 ]




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Anode oxidation

Anode process, 1.20

Anodes oxides

Anodic coupling

Anodic oxidation

Anodic oxides

Anodic processes

Anodization process

Coupled processes

Coupling processes

Kolbe

Kolbe coupling

Kolbe oxidation

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