Grignard reagents olefination using

The Bamford-Stevens reaction and the Shapiro reaction share a similar mechanistic pathway. The former uses a base such as Na, NaOMe, LiH, NaH, NaNHa, heat, etc., whereas the latter employs bases such as alkyllithiums and Grignard reagents. As a result, the Bamford-Stevens reaction furnishes more-substituted olefins as the thermodynamic products, while the Shapiro reaction generally affords less-substituted olefins as the kinetic products. 

Electron-rich olefins are nucleophilic and therefore subject to thermal cleavage by various electrophilic transition metal complexes. As the formation of tetraaminoethylenes, i.e., enetetramines, is possible by different methods, various precursors to imidazolidin-2-ylidene complexes are readily available. " Dimerization of nonstable NHCs such as imidazolidin-2-ylidenes is one of the routes used to obtain these electron-rich olefins [Eq. (29)]. The existence of an equilibrium between free NHC monomers and the olefinic dimer was proven only recently for benzimidazolin-2-ylidenes. In addition to the previously mentioned methods it is possible to deprotonate imidazolidinium salts with Grignard reagents in order to prepare tetraaminoethylenes. " The isolation of stable imidazolidin-2-ylidenes was achieved by deprotonation of the imidazolidinium salt with potassium hydride in THF. ... 

Ab initio calculations also confirm that the use of an allyl magnesium alkoxide in place of the alcohol functionality will lead to high or complete stereoselectivity (138). When homoallylic alcohols are used, the Kanemasa protocol afforded the respective isoxazolines with poor stereoselectivity ( 55 45) in the case of terminal aUcenes, but with very high diastereoselectivity (up to 96 4) in the reaction of cis-1,2-disubstituted olefins (136). Extension of this concept to the reaction of a-silyl allyl alcohols also proved feasible and produced the syn (threo) adducts as nearly pure diastereomers (>94 6) (137). Thus, the normal stereoselectivity of the cycloaddition to the Morita-Baylis-Hillman adducts (anti > syn, see above) can be reversed by prior addition of a Grignard reagent (176,177). Both this reversal... 

Anodic oxidation of Grignard reagents (5) in the presence of styrene (30), butadiene (36) or vinyl ethyl ether (37) was investigated by Schafer and Kuntzel as an interesting (for preparative use) extension of other anodic reactions with olefins. The electrolysis was carried out at constant current density at Pt, Cu or graphite electrodes. It was found that the products obtained depend on the electrode material, as is seen from the data presented in Table 9. 

Webb, L. J. and Lewis, N. S. Comparison of the electrical properties and chemical stability of crystalline silicon(lll) surfaces alkylated using Grignard reagents or Olefins with Lewis acid catalysts. Journal of Physical Chemistry 107, 5404 (2003). 

Usually, after hydrolysis, the alcohol is the product, but sometimes (especially with aryl aldehydes) elimination follows directly and the product is an olefin. By the use of Bu,P along with Zn, the olefin can be made the main product,454 making this an alternative to the Wittig reaction (6-47). Since Grignard reagents cannot be formed from a-halo esters, the method is quite useful, though there are competing reactions and yields are sometimes low. A similar reaction (called the Blaise reaction) has been carried out on nitriles 455... 

As mentioned in Section 4.2.2.6, dithioacetals can be used in coupling reactions with Grignard reagents in sequences leading to the formation of carbon-carbon single and double bonds. The metal-catalysed reactions depicted here exemplify their uses for olefination reactions, which opened the way to many useful synthetic applications [319],... 

Prochiral acyclic olefins have been used in the reaction with an aryl Grignard reagent. With the complex of nickel(II) chloride and chiraphos (2), a high enantioselectivity could be obtained, albeit with poor rcgiosclecdvity (Eq. 8E.26) [204]. When the sterically more bulky 1,3-diphenylallyl... 

As discussed in connection with olefin-coupling reactions and shown in Fig. 4, the coupling of vinyl Grignard reagents is stereospecific and dependent upon the transition metal catalyst used (32, 33). The dimerization of ethylene, shown in Fig. 6, was also shown to produce primarily the terminal olefin 1-butene (35). The size of the metal has also been shown to influence the course of the catalyzed oligomerization reactions of butadiene. When bis-(ir-allyl) metal complexes are used as... 

When compounds V (R = ethyl, isopropyl, cyclopentyl, n-butyl, or tert-butyl) have been heated 30-50°C above their melting points, VIII and the corresponding olefins have been obtained by (3 elimination (87,94). The course of the reaction has been controlled by the use of the deuterium-labeled compound V (R = CD2Me). It has been shown that all of the deuterium occurred in the ethylene formed by thermolysis (94). When R is methyl or phenyl, the thermolysis of V results in formation of IX. The styryl derivatives of V (R = cis-CH=CHPh and trans-CH=CHPh) have also been synthesized from VI and the corresponding Grignard reagents (94). Interestingly, thermolysis of these deriva-... 

The acid or base elimination of a diastereoisomerically pure p-hydroxysilane, 1, (the Peterson olefination reaction4) provides one of the very best methods for the stereoselective formation of alkenes. Either the E- or Z-isomer may be prepared with excellent geometric selectivity from a single precursor (Scheme 1). The widespread use of the Peterson olefination reaction in synthesis has been limited, however, by the fact that there are few experimentally simple methods available for the formation of diastereoisomerically pure p-hydroxysilanes.56 One reliable route is the Cram controlled addition of nucleophiles to a-silyl ketones,6 but such an approach is complicated by difficulties in the preparation of (a-silylalkyl)lithium species or the corresponding Grignard reagents. These difficulties have been resolved by the development of a simple method for the preparation and reductive acylation of (a-chloroalkyl)silanes.7... 

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