Barton esterification

Barton Esterification Reductive Decarboxylation. O-Acyl thiohydroxamates or Barton esters are useful precursors of carbon-centered radicals via thermolysis or photolysis. Several different methods are available for converting carboxylic acids into Barton esters (eq 1). These reactions generally proceed via the attack of a 2-mercaptopyridine-N-oxide salt on an activated carboxylic acid that has either been preformed (acid chloride, mixed anhydride) or generated in situ (with 1,3-dicyclohexylcarbodiimide or tri-n-butylphosphine + 2,2 -dithiodipyridine-l,r-dioxide). However, HOTT has the distinct advantages of (1) being easy to prepare and handle without the need for any special precautions, (2) facilitates efficient Barton esterification of carboxylic acids, and (3) simplifies subsequent work-up and purifications by avoiding the need to remove by-products like 1,3-dicyclohexylurea. 

Barton Esterification Radical Addition. One of the best examples illustrating the benefits of HOTT for this transformation is shown in eq 5. The Barton esterification of this very hindered acid was followed by IR spectroscopy by monitoring the disappearance of the carbonyl stretch of the acid (1740 cm ) and the appearance of the carbonyl stretch of the Barton ester (1810 cm ). Barton esterification using HOTT was complete within 20 min, whereas over 4 h was required when using the combination of DCC and 2-mercaptopyridine-iV-oxide. 

HOTT was used to effect Barton esterification in a novel approach to 1, 3, 5,... (2n+l) polyols based on iterative stereocon-trolled homologation of chiral hydroxyalkyl radicals (eq 6). General notes As with most Barton esterifications, the reaction should be performed in the dark and under anhydrous conditions. 

The control of chemical reactions (e.g., esterification, sulfonation, nitration, alkylation, polymerization, oxidation, reduction, halogenation) and associated hazards are an essential aspect of chemical manufacture in the CPI. The industries manufacture nearly all their products, such as inorganic, organic, agricultural, polymers, and pharmaceuticals, through the control of reactive chemicals. The reactions that occur are generally without incident. Barton and Nolan [1] examined exothermic runaway incidents and found that the principal causes were ... 

Scheme 44 summarizes an addition reaction by the Barton method. Thiohydroxamate esters (32) are readily prepared and isolated, but, more typically, they are generated in situ. Experimental procedures have been described in detail148151 and often entail the slow addition of an acid chloride to a refluxing chlorobenzene solution of the readily available sodium salt (31), dimethylaminopyridine (DMAP, to catalyze the esterification), and excess alkene. The products are usually isolated by standard aqueous work-up and chromatographic purification. 

Alkylative esterification of carboxylic acids with alkyl halides are effected by action with TMG (1) [65]. An ester is given by the TMG (1) mediated reaction of y-hydroxy-a,p-unsaturated carboxylic acid with methyl iodide without lactone formation after isomerization [65a]. Barton s base effectively works in the alkylation of sterically hindered carboxylic acid [3]. Ethanolysis of the acetate of tertiary alcohol occurred easily in 86% yield in the presence of BTMG (2) [66] (Scheme 4.24). 

Many new methods for the preparation of alkanes by reductive removal of functional groups have been reported during the year. Barton and his co-workers have presented a new radical decarboxylation for the conversion of carboxylic acids into hydrocarbons. Following esterification with /ran5-9-hydroxy-10-phenylthio-(or -10-chloro-)9,10-dihydrophenanthrene, a primary, secondary, or tertiary carboxylic acid is smoothly reduced under neutral conditions by tri-n-butylstannane and a radical initiator (e.g. Scheme 1). Formation of phenanthrene... 

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