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Alkenyl Grignard compounds

Transition metal-catalyzed cross-coupling reactions between vinyl organometallic compounds and unactivated alkyl halides that can be usually performed with palladium, nickel and cobalt are of particular synthetic interest [37-39]. Recently, the groups of Cahiez [48] and Cossy [49] concurrently reported the first iron-catalyzed reaction of alkenyl Grignard compounds with primary and secondary alkyl halides (X=Br, I) (Scheme 5.15). The two protocols basically differ in the iron source... [Pg.164]

Alkenyl Grignard compounds, too, can be alkenylated as well as arylated. [Pg.701]

In all these reactions, any existing configuration of any stereogenic double bond—whether it be in the alkenyl bromide or iodide or in the alkenyl Grignard compound- is completely retained. The reactions in Figure 16.10 provide good examples. [Pg.702]

The order of reactivity of organic halides is I > Br > Cl > F. Although organic iodides are the most reactive, they produce more Wurtz coupling products through the radical oxidative addition process. Thus, it is usually advisable to use the chlorides or bromides, except in the case of aromatic iodides and methyl iodide. 1-Alkenyl Grignard compounds are obtained by the direct reaction of magnesium and vinylic halides in THF [6], but the reaction is not completely stereospecific and the retention of the stereochemistry of haloalkenes varies from 60-90% [7]. The difficulty associated... [Pg.334]

In 2002, Furstner and coworkers reported that aryl halides react with Grignard reagents under the conditions previously used for the coupling of alkenyl halides. They proposed that the active iron species is Fe(MgX)2, a complex described by Bogdanovic and coworkers ° a few years earlier (Scheme 30). This iron(-II) species is formed by addition of four equivalents of the Grignard compounds to FeCl2. [Pg.610]

As described in Section II, the preparation of 1,1-dizincioalkane can be achieved not only by reduction of 1,1-dihaloalkane, but also by allylzincation of alkenyl metal compounds. The reaction of allylzinc with alkenyl Grignard reagent, which is followed by the addition of aldehydes, gives dienes as shown in Scheme 1511,41. [Pg.657]

Their advantage over other types of dendrimers is their straightforward synthesis and, most importantly, their chemical and thermal stabilities. Two distinct steps characterize their synthesis a) an alkenylation reaction of a chlorosilane compound with an alkenyl Grignard reagent, and b) a Pt-cata-lyzed hydrosilylation reaction of a peripheral alkenyl moiety with an appropriate hydrosilane species. Scheme 2 shows the synthesis of catalysts Go-1 and Gi-1 via this methodology. In this case, the carbosilane synthesis was followed by the introduction of diamino-bromo-aryl groupings as the precursor for the arylnickel catalysts at the dendrimer periphery. The nickel centers of the so-called NCN-pincer nickel complexes were introduced by multiple oxidative addition reactions with Ni(PPh3)4. [Pg.9]

The most important substrates for substitutions of this type are alkenyl and aryl triflates, bromides, or iodides (Sections 16.1-16.4). The most important organometallic compounds to be introduced into the substrates contain Cu, Mg, B, Zn or Sn. The metal-bound C atom can be sp2-, sp2-, or. sp-hybridized in these compounds, and each of these species, in principle, is capable of reacting with unsaturated substrates. Organocopper compounds often (Section 16.1, 16.2), but not always substitute without the need for a catalyst (Section 16.4.5). Grignard compounds substitute in the presence of catalytic amounts of Ni complexes (Section 16.3), while organoboron (Section 16.4.2), organozinc (Section 16.4.3) and organotin (Section 16.4.4) compounds are typically reacted in the presence of Pd complexes (usually Pd(PPhj)4). [Pg.691]

Alkenylation and Aiylation of Grignard Compounds (Kumada Coupling)... [Pg.701]

Primary alkyl Grignard compounds can be alkenylated (Figure 16.10) and arylated (in analogy to Figure 16.11). [Pg.701]

Fig. 16.10. Nickel-catalyzed alkenylation of Grignard compounds occurrence of stereoselectivity and stereospecificity. Fig. 16.10. Nickel-catalyzed alkenylation of Grignard compounds occurrence of stereoselectivity and stereospecificity.
All of the alkenylations and arylations discussed in this section follow the common mechanism exemplified in Figure 16.18. The steps shown in Figure 16.18 may involve more than one elementary reaction, as in the case of the mechanistic course of the Ni-catalyzed C,C coupling with Grignard compounds (Figure 16.12). It should be noted that the basic sequence of steps is very much the same in Figures 16.18 and 16.12. [Pg.709]

Aromatic Grignard compounds can be arylated (Figure 13.6) and alkenylated (in analogy to Figure 13.5). [Pg.523]

The quasi-complex compounds, as well as the complexes discussed above, led us into a domain which was nearly terra incognita at that time, namely, the substituted (j3-chloro, j8-alkyl, )3-keto) vinyl organometallics. Thus, the simplest of metal vinyls became the objective of our work, and the vinyl, isopropenyl, propenyl, and styryl derivatives of elements such as Hg, B, Tl, Ge, Sn, Si, P, As, Sb, and Bi were studied in collaboration with Freidlina and Borisov. Apart from the procedures mentioned in Section V, vinyl-lithium and vinyl Grignard compounds were used for the synthesis. Note that the highest valence alkenyl derivatives of the type RjSb were reported by us (181-205). [Pg.34]

In some cases, the preparation of solutions of alkenyllithium or Grignard compounds is synthetically attractive. Vinyl bromide, for example, can be converted in THF with magnesium into vinylmagnesium bromide with excellent results [74]. This Grignard solution can be used for the preparation of a number of derivatives, e.g. H2C=CH—SiMe3 and (H2C=CH)4Sn. Other aliphatic alkenyl-magnesium bromides may be obtained in a similar way. [Pg.46]

In Grignard reactions, Mg(0) metal reacts with organic halides of. sp carbons (alkyl halides) more easily than halides of sp carbons (aryl and alkenyl halides). On the other hand. Pd(0) complexes react more easily with halides of carbons. In other words, alkenyl and aryl halides undergo facile oxidative additions to Pd(0) to form complexes 1 which have a Pd—C tr-bond as an initial step. Then mainly two transformations of these intermediate complexes are possible insertion and transmetallation. Unsaturated compounds such as alkenes. conjugated dienes, alkynes, and CO insert into the Pd—C bond. The final step of the reactions is reductive elimination or elimination of /J-hydro-gen. At the same time, the Pd(0) catalytic species is regenerated to start a new catalytic cycle. The transmetallation takes place with organometallic compounds of Li, Mg, Zn, B, Al, Sn, Si, Hg, etc., and the reaction terminates by reductive elimination. [Pg.125]

See other pages where Alkenyl Grignard compounds is mentioned: [Pg.201]    [Pg.426]    [Pg.701]    [Pg.782]    [Pg.327]    [Pg.522]    [Pg.522]    [Pg.523]    [Pg.525]    [Pg.578]    [Pg.46]    [Pg.56]    [Pg.1465]    [Pg.1465]    [Pg.5347]    [Pg.446]    [Pg.1464]    [Pg.1464]    [Pg.5346]    [Pg.152]    [Pg.1]    [Pg.113]    [Pg.46]   
See also in sourсe #XX -- [ Pg.523 ]



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Alkenyl bromides Grignard compound reactions

Alkenyl compounds

Alkenyl iodides Grignard compound reactions

Grignard compounds

Grignards, 1-alkenyl

Nickel-catalyzed alkenylation Grignard compound

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