Kolbe electrolytic synthesis

This reaction is of wide scope it is limited only by the availability of the appropriate 1,4-diketone. 1,4-Diketones are easily accessible, e.g. by the Nef reaction. 

Methods for the synthesis of pyrroles are of importance, since the pyrrole unit is found in natural products widespread in nature. For example a pyrrole unit is the building block of the porphyrin skeleton, which in turn is the essential structural subunit of chlorophyll and hemoglobin. 

The anodic oxidation of the carboxylate anion 1 of a carboxylate salt to yield an alkane 3 is known as the Kolbe electrolytic synthesis By decarboxylation alkyl radicals 2 are formed, which subsequently can dimerize to an alkane. The initial step is the transfer of an electron from the carboxylate anion 1 to the anode. The carboxyl radical species 4 thus formed decomposes by loss of carbon dioxide. The resulting alkyl radical 2 dimerizes to give the alkane 3  

The radical mechanism is supported by a number of findings for instance, when the electrolysis is carried out in the presence of an olefin, the radicals add to the olefinic double bond styrene does polymerize under those conditions. Side products can be formed by further oxidation of the alkyl radical 2 to an intermediate carbenium ion 5, which then can react with water to yield an alcohol 6, or with an alcohol to yield an ether 7  

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The reaction is likely to proceed by a radical-chain mechanism, involving intermediate formation of carboxyl radicals, as in the related Kolbe electrolytic synthesis. Initially the bromine reacts with the silver carboxylate 1 to give an acyl hypobromite species 3 together with insoluble silver bromide, which precipitates from the reaction mixture. The unstable acyl hypobromite decomposes by homolytic cleavage of the O-Br bond, to give a bromo radical and the carboxyl radical 4. The latter decomposes further to carbon dioxide and the alkyl radical 5, which subsequently reacts with hypobromite 3 to yield the alkyl bromide 2 and the new carboxyl radical 4Z... 

Suitable starting materials for the Kolbe electrolytic synthesis are aliphatic carboxylic acids that are not branched in a-position. With aryl carboxylic acids the reaction is not successful. Many functional groups are tolerated. The generation of the desired radical species is favored by a high concentration of the carboxylate salt as well as a high current density. Product distribution is further dependend on the anodic material, platinum is often used, as well as the solvent, the temperature and the pH of the solution." ... 

Radicals, (34), that subsequently dimerise, are also obtained through the anodic oxidation of carboxylate anions, RCO20, in the Kolbe electrolytic synthesis of hydrocarbons ... 

Kolbe electrolytic synthesis. Formation of hydrocarbons by the electrolysis of alkali salts of carboxylic acids (decarboxylative dimerization). 

Koch-Haaf Carboxylations Kochi Reaction Koenigs-Knorr Synthesis Kolbe Electrolytic Synthesis Kolbe-Schmitt Reaction Komer-Contardi Reaction Kostanecki Acylation Krafft Degradation Krapcho Decarbalkoxylation... 

Kolbe Electrolytic Synthesis Crum Brown-Walker Reaction... 

Weedon BCL (1960) The kolbe electrolytic synthesis In Raphael, AR, Taylor, EC, Wynberg, H (eds) Advances in organic chemistry methods and results. Interscience Publishers Inc, New York, 1, p. 1... 

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