Dimetalated compounds

The 1,1-dimetallic compounds, R2C(SnMe3)ZnBr, were oxidized by dry air at —10 to 0°C in the presence of Me3SiCl to give aldehydes or ketones, R2C=0. In a related indirect method, arylthallium bis(trifluoroacetates) (prepared by 12-21) can be converted to phenols by treatment with lead tetraacetate followed by triphenylphosphine, and then dilute NaOH. Diarylthallium trifluoroacetates undergo the same reaction. ... 

The violence of superbasic slurries towards functionalized organic molecules means that they are at their most effective with simple hydrocarbons they also tolerate ethers and fluoro substituents. LiCKOR will deprotonate allyUc, benzylic, vinylic, aromatic and cyclopropane C—H bonds with no additional assistance. From benzene, for example, it forms a mixture of mono and dimetallated compounds 617 and 618 (Scheme 241) . ( Li/K indicates metallation with a structurally ill-defined mixture of lithium and potassium.)... 

A molecular structure, similar to that of hexasilylated benzene derivative 229, was obtained from tetracyclic hexasilylbenzene 230 by Kira, Sakurai and coworkers, where the six silicon centres are incorporated in three five-membered ring systems (Scheme 80) °. In dimetalated compound 231, two lithium centres, coordinated by a quinuclidine ligand each, are capping the phenyl ring plane from both sides in the solid state. Moreover, it could be found that compound 231 has a thermally accessible triplet state, investigated by temperature-dependent ESR spectroscopy °°. 

The reactivity of the dimetallic compounds 186a and 186b was then investigated and these species were less reactive than their formulas would lead to predict, as no reaction occurred with ketones, esters, Michael acceptors or trimethylsilyl chloride. In the presence of BF3 OEt2, addition occurred to aldehydes and led after /3-elimination to the corresponding olefination products 189 with good to excellent (E) stereoselectivity (equation 92)127. 

Three transmetallation reactions are known. The reaction starts by the oxidative addition of halides to transition metal complexes to form 206. (In this scheme, all ligands are omitted.) (i) The C—C bonds 208 are formed by transmetallation of 206 with 207 and reductive elimination. Mainly Pd and Ni complexes are used as efficient catalysts. Aryl aryl, aryl alkenyl, alkenyl-alkenyl bonds, and some alkenyl alkyl and aryl-alkyl bonds, are formed by the cross-coupling, (ii) Metal hydrides 209 are another partner of the transmetallation, and hydrogenolysis of halides occurs to give 210. This reaction is discussed in Section 3.8. (iii) C—M bonds 212 are formed by the reaction of dimetallic compounds 211 with 206. These reactions are summarized in Schemes 3.3-3.6. 

Palladium-catalysed reactions of dimetallic compounds 358 such as X2B—BX2, R3Sn—SnR3, R3S11—SiR3 or R3Si—SiR3 with halides via oxidative addition and transmetallation are useful for the preparation of carbon main group metal bonds 359. 

Metalametallations of alkenes and alkynes are useful methods for the construction of 1,2-dimetala-alkanes and 1,2-dimetala-l-alkenes, which react subsequently with suitable electrophiles to form substituted alkanes and alkenes. Metalametallation is carried out usually with bimetallic reagents of the type R Si-M R, or R Sn-M R in which M = B, Al, Mg, Cu, Zn, Si or Sn. Some metalametallations proceed without catalysts Cu, Ag and Pd compounds are good catalysts. The metalametallation with bimetallic compounds, such as Si-B, Si-Mg, Si-Al, Si-Zn, Si-Sn, Si-Si, Sn-Al or Sn—Sn bonds, catalysed by transition metal complexes, is explained by the oxidative addition of the bimetallic compounds to form 478, and insertion of alkene generates 479. Finally 1,2-dimetallic compounds 480 are formed by reductive elimination. Dimetallation of alkynes proceeds similarly to give 481. Dimetallation is syn addition. 

Organo-gew-dimetallic compounds that possess two nucleophilic see Lewis Acids Bases) sites on one carbon atom... 

Substituted gem-dimetallic compounds, readily obtained via allylation of alkenyl organometallics, react with aldehydes in the presence of BF3-Et20 but do not react with ketones. When alkylidenemalonates are used instead of aldehydes, the Z-olefins see (E) (Z) Isomers) are obtained with a very high stereoselectivity (Scheme 35). A transmetallation reaction with copper cyanide significantly increases the reactivity of gm-dimetallic derivatives via formation of 1,1-zinca cyanocuprates. Indeed, when these compounds react with... 

A related approach to 1,1-dimetallated compounds relies on the allylation of 1-alkenyl-magnesium, -lithium, and - uminum derivatives (23) with allylzinc bromides (22), which proceeds readily at 35 C (Scheme 7 Table 4). The resulting gem-dimetallic intermediates can be trapped by protonation (24 26,25 - 29), stannylation (24 - 27) or, more interestingly, with aldehydes in the presence of BFs OEt (e.g. 24a - 28). The dimetallated species (24) were also trapped with alkylidene malonates, l2/H30, ... 

The 1,1-dimetallic compounds R2C(SnMe3)ZnBr were oxidized by dry air at -10 to 0°C in the presence of MeaSiCl to give aldehydes or ketones R2C=0. ... 

Bertini, F., Grasselli, P., Zubiani, G., Cainelli, G. Geminal dimetallic compounds. Reactivity of methylene magnesium halides and related compounds. General carbonyl olefination reaction. Tetrahedron 9 0, 26,1281-1290. 

Cyclic oligostannacycloalkanes, [R2Sn(CH2) ]m, can be prepared from the reaction between tin dihalides and organodimetallic compounds, or tin dimetallic compounds and organic dihalides. Many of these reactions give mixtures of oligomers from which the individual compounds are separated, usually by chromatography, and sometimes in only low yield (e.g. equation 10-18).11... 

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