Vinyl sulfones electrophilic additions

However, when the bulky substituent is no longer present at the electrophilic carbon atom, the addition of the olefin to the morpholine enamine of cyclohexanone leads largely to the tetrasubstituted isomer. For instance the reaction of this enamine with phenyl vinyl sulfone gave a 1 3 mixture of... 

Vinyl trifluoromethanesulfonates (triflates) are a new class of compounds, unknown before 1969, that have been used most extensively in solvolytic studies to generate vinyl cations.2,3,812 Three methods have been used to prepare these sulfonic esters. The first, involving the preparation and decomposition of acyltriazines,4 requires several steps to prepare the acyltriazines and is limited to the preparation of fully substituted vinyl triflates. The second method involves the electrophilic addition of trifluoromethanesulfonic acid to acetylenes5,8,15 and, consequently, is not applicable to the preparation of trisubstituted vinyl triflates and certain cyclic vinyl triflates. However, this second procedure is relatively simple and often gives purer products in higher yield than the subsequently discussed reaction with ketones. Table I lists vinyl triflates that have been prepared by this procedure. ... 

Generally, treatment with electron-deficient olefins such as nitroethylene or vinyl sulfone is effective for radical addition reactions, since alkyl radicals derived from O-acyl esters (2) are nucleophilic and take SOMO-LUMO interaction. However, treatment of O-acyl esters ) derived from perfluoroalkyl carboxylic acids (RfC02H) generates electrophilic radicals, Rf, which react preferably with electron-rich olefins such as vinyl ether, as shown in eq. 8.16 [52]. 

Electrophilic additions to vinyl sulfoxides and sulfones allow for further functionalization of these compounds at the a-position. Deprotonation of the a-hydrogen, under appropriate conditions, gives rise to a-vinyl anions which can be trapped by electrophiles. This protocol has been employed in the synthesis of a diverse range of compounds, such as 34 and 37, 40 and 43, and 46 (see Schemes 9, 10, and 11, respectively). Both enantiomers of optically pure propargylic alcohols (115) were conveniently prepared by the reaction of the a-vinyl anion of 2-(trimethylsilyl) vinyl... 

Nitroalkenes, vinyl sulfones and vinylphosphonium salts have been shown as good Michael acceptors for 2-lithio-l,3-dithiane derivatives. Nitroalkene sugar derivative 246 has been used as electrophile for the synthesis of branched-chain cyclitols397 - 399. Seebach and Langer studied the addition to simple nitroalkenes using the chiral solvent (,S ,.S )-DDB (247) with some degree of diastereoselectivity400,401. 

The addition of electrophilic reagents to chiral a,/3-unsaturated sulfoxides is also accompanied by asymmetric induction. Stirling and Abbott (318,322) found that the addition of bromine to the optically active (.R)-vinyl-p-tolyl sulfoxide 319 yields a mixture of diastereo-meric a,/3-dibromosulfoxides 320. Oxidation of this mixture gives the optically active sulfone 321, with a center of chirality at the a-carbon atom only. The optical purity (32%) of this sulfone was estimated by comparing its specific rotation with that obtained as a result of oxidation of diastereomerically pure sulfoxide (/ )-320. The assignment of configuration at the a-carbon atom was based on the analysis of the polarizabilities of substituents. 

This reaction illustrates a stereoselective preparation of (Z)-vinylic cuprates, 5 which are very useful synthetic Intermediates. They react with a variety of electrophiles such as carbon dioxide,5,6 epoxides,5,6 aldehydes,6 allylic halides,7 alkyl halides,7 and acetylenic halides 7 they undergo conjugate addition to a,6-unsaturated esters,5 6 ketones,6 aldehydes,6 and sulfones.8 Finally they add smoothly to activated triple bonds6 such as HCSC-OEt, HC3C-SEt, HC=C-CH(0Et)2. In most cases these cuprates transfer both alkenyl groups. The uses and applications of the carbocupration reaction have been reviewed recently.9 The configurational purity in the final product 1s at least 99.951 Z in the above transformations. 

Many common reactions of aliphatic amines, ethers, and sulfides 1 involve initial addition of an electrophilic reagent utilizing the lone pair of electrons on the heteroatom salts, quaternary salts, coordination compounds, amine oxides, sulfoxides, and sulfones are formed in this way. Corresponding reactions are very rare (cf. Section 3.3.1.3) with pyrroles, furans, and thiophenes. These heterocycles react with electrophilic reagents at the carbon atoms 2, 3 rather than at the heteroatom. Vinyl ethers and enamines 4 show intermediate behavior, reacting frequently at the -carbon but sometimes at the heteroatom. 

The traditional scope for this reaction involved coupling alkenyl or aryl iodides or bromides with aryl, alkenyl, or alkynylzinc halides. However, recent modifications have allowed the scope to be extended to include additional electrophiles see Electrophile) such as aryl and vinyl chlorides, sulfonate esters, aryl ethers, and substrates with... 

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