Alcohols halo hydrins

A large variety of methods is applicable to the formation of isolated double bonds. This permits selection of reagents compatible with other functionality present. Alcohol dehydration, ester elimination and other nonreductive p eliminations are the most common methods. Reductive elimination of halo-hydrins, vic-dihalides, etc., and of a variety of ketone derivatives has also been used. 

The mechanism of the reaction is well-known. The first step is formation of a carbanion, followed by nucleophile addition to the carbonyl carbon atom halo-hydrin alcoholates are produced finally, ring-closure takes place by intramolecular substitution. The stereochemistry of the reaction is much disputed the reason why a unified viewpoint has not emerged is that the configuration of the end-product is influenced by the structure of the starting compound (including steric hindrance), the base employed, and solvation by the solvent, sometimes in an unclear manner. The stereochemical course of the reaction is controlled by the kinetic and thermodynamic factors in the second step the structure of the oxirane formed is decided by the reversibility of the aldolization and the reaction rate of the ring-closure. 

Onium salts can also be used to support reagents that would transform a substrate. After reaction the IL phase can be recovered and the reagent regenerated for being reused in another cycle. For example, carboxylic acids have been supported on onium halides. Simply synthesized by quatemarisation of methylimidazole followed by acid hydrolysis, this compound can react with epoxides to afford halo-hydrines in 76-95% yields [58], Additionally, an OS supported version of TEMPO has been used in oxidation of alcohol into ketone [59] (Fig. 21). 

Carbonyl Compounds by Oxidation of Alcohols and Aldehydes. Salts of palladium, in particular PdCl2 in the presence of a base, catalyze the CCI4 oxidation of alcohols to aldehydes and ketones. Allylic alcohols carrying a terminal double bond are transformed to 4,4,4-trichloro ketones at 110 °C, but yield halo-hydrins at 40 °C. These can be transformed to the corresponding trichloro ketones under catalysis of palladium acetate (eq 56). The latter transformation could be useful for the formation of ketones from internal alkenes provided the halohydrin formation is regioselective. 

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