Allylsilane

Conventional synthetic schemes to produce 1,6-disubstituted products, e.g. reaction of a - with d -synthons, are largely unsuccessful. An exception is the following reaction, which provides a useful alternative when Michael type additions fail, e. g., at angular or other tertiary carbon atoms. In such cases the addition of allylsilanes catalyzed by titanium tetrachloride, the Sakurai reaction, is most appropriate (A. Hosomi, 1977). Isomerization of the double bond with bis(benzonitrile-N)dichloropalladium gives the y-double bond in excellent yield. Subsequent ozonolysis provides a pathway to 1,4-dicarbonyl compounds. Thus 1,6-, 1,5- and 1,4-difunctional compounds are accessible by this reaction. 

The reaction of phenylmethylenecyclopropane with trimethylsilyl cyanide catalyzed by PdCl2 affords the allylsilane 81 in 71% yield[63]. 

Similai selectivity is observed in the synthesis of allylsilanes where X = CF3SO3 and Y = Si(CH3) 3 (304). Alkenyl- and alkynylborates containing a leaving group in the y-position rearrange to aUyhc and aUenic boranes, respectively (305). 

Me3SiCH2CH=CH2i TsOH, CH3CN, 70-80°, 1-2 h, 90-95% yield. This silylating reagent is stable to moisture. Allylsilanes can be used to protect alcohols, phenols, and carboxylic acids there is no reaction with thiophenol except when CF3S03H is used as a catalyst. The method is also applicable to the formation of r-butyldimethylsilyl derivatives the silyl ether of cyclohexanol was prepared in 95% yield from allyl-/-butyldi-methylsilane. Iodine, bromine, trimethylsilyl bromide, and trimethylsilyl iodide have also been used as catalysts. Nafion-H has been shown to be an effective catalyst. 

CONJUGATE ALLYLATION OF a. -UNSATURATED KETONES WITH ALLYLSILANES 4-PHENYL-6-HEPTEH-2-0NE (6-Hepten-2-one, 4-pheny1-)... 

CONJUGATE ALLYLATION OF a,g-ENONES WITH ALLYLSILANES PROMOTED BY TITANIUM TETRACHLORIDE Conditions... 

Me3S1CH2C(CH3)CH2. Three equivalents of the allylsilane were used. 9(1V) trans-Me3SiCH2CH=CHCH3. a... 

Titanium(IV) is a powerful but selective Lewis acid which can promote the coupling of allylsilanes with carbonyl compounds and derivatives In the presence of titanium tetrachlonde, benzalacetone reacts with allyltnmethylsilane by 1,4-addition to give 4-PHENYL-6-HEPTEN-2-ONE. Similarly, the enol silyl ether of cyclopentanone is coupled with f-pentyl chloride using titanium tetrachlonde to give 2-(tert-PENTYL)CYCLOPENTANONE, an example of a-tert-alkylation of ketones. 

Allylsilanes and allylstannanes are also reactive toward electrophiles and usually undergo a concerted elimination of the silyl substituent. Several examples are shown below. 

Allylation of perfluoroalkyl halides with allylsilanes is catalyzed by iron or ruthenium carbonyl complexes [77S] (equation 119) Alkenyl-, allyl-, and alkynyl-stannanes react with perfluoroalkyl iodides 111 the presence ot a palladium complex to give alkenes and alkynes bearing perfluoroalkyl groups [139] (equation 120)... 

Similarly, trimethylsilyl inflate can be used as a catalyst for the alkylation of 2 methoxy 1,3-oxazolidines [104] or 1-acetoxyadamantane [105] with allylsilane and for the reduction of acetals to ethers with trialkylsilanes [106]... 

Oshima and coworkers reported the preparation of allylsilanes such as 148 by ringopening reactions of three-membered rings such as aziridines 147 with silylalu-minium reagents as shown in Scheme 2.38 [58]. 

Hodgson and coworkers extended this concept to epoxides of unsaturated cyclic ethers 128 [5] and amines 130 [46, 47] (Scheme 5.28). It is interesting that the use of trimethylsilylmethyllithium as the organolithium in this case resulted in substituted allylsilanes 129 and 131 (R = CH2SiMe3) presumably the epoxide ring protons of 128 and 130 are more acidic than those of a simple terminal epoxide (see Scheme 5.26). 

Essentially all allylsilanes (M = SiR3, Section D.l.3.3.3.5.) with the exception of fluorosil-iconates11 and most of the trialkyl(allyl)stannancs (Section D.l. 3.3.3.6.), which have only very weak Lewis acidic properties, require a strong Lewis acid to trigger the reaction with a carbonyl compound by the preceding formation of an x-oxycarbenium ion, which attacks the allylic compound in an ionic open-chain pathway. These Lewis acid catalyzed carbonyl additions offer new possibilities for the control of the simple and induced diastereoselectivity12. 

Lewis acid catalyzed carbonyl addition of allylsilanes (Section D.l.3.3.3.5.) and allylstannanes (Section D.l.3.3.3.6.) usually proceed with clean allylic inversion (Section D.l.3.3.1.2.). Since these compounds are prepared by several routes and are also stable enough to be purified, each regioisomer can be approached. 

In Lewis acid catalyzed carbonyl additions of allylsilanes and -stannanes, syn diastereoselectiv-ity predominates, irrespective of the double-bond configuration, indicating that open-chain transition states are involved. 

Allylsilanes or allylstannanes in the presence of a bidentate Lewis acid such as tin(IV) chloride, titanium(IV) chloride, zinc chloride, and magnesium bromide as well as diallylzinc, are promising choices (Table 1). 

A large number of publications appeared on these aspects5, but most of these studies did not address stereochemical questions. In most cases, a given synthetic problem can be better solved by other allylmetals. Grignard reagents have some importance as intermediates for the preparation of allylboronates (Section D.1.3.3.3.3.2.1.), allylsilanes (Section D.1.3.3.3.5.2.L), allyl-stannanes (Section D. 1.3.3.3.6.2.1.1.), or allyltitanium derivatives (Section D.I.3.3.3.8.2.). 

Chelation control does not operate in the addition of 2-butenyl Grignard reagents to a-oxyalkanals, since with (racemic) 2-benzyloxy-, 2-(benzyloxymethoxy)- and 2-(t< rt-butyldi-methylsilyoxy)propanal similar ratios of isomers are formed28. Several cations were investigated, but the best choices, e.g., allylboronates or allylsilanes, were not included in this study. 

The cyclohexyloxy(dimethyl)silyl unit in 8 serves as a hydroxy surrogate and is converted into an alcohol via the Tamao oxidation after the allylboration reaction. The allylsilane products of asymmetric allylboration reactions of the dimethylphenylsilyl reagent 7 are readily converted into optically active 2-butene-l, 4-diols via epoxidation with dimethyl dioxirane followed by acid-catalyzed Peterson elimination of the intermediate epoxysilane. Although several chiral (Z)-y-alkoxyallylboron reagents were described in Section 1.3.3.3.3.1.4., relatively few applications in double asymmetric reactions with chiral aldehydes have been reported. One notable example involves the matched double asymmetric reaction of the diisopinocampheyl [(Z)-methoxy-2-propenyl]boron reagent with a chiral x/ -dialkoxyaldehyde87. 

Allylsilanes are widely used in organic synthesis1 4. They are stable with respect to 1,3-migra-tion of the silicon indeed high temperatures or catalysts are required for 1,3-equilibration5. The preparation of allylsilanes has been reviewed recently6-7. 

Allylsilanes are readily available by silylation of allylmetal reagents. If the allylmetal reagent is unsymmetric, mixtures of regioisomers are usually obtained1,8. 

Symmetric allylsilanes and unsymmetric allylsilanes, in which the silyl substituent is at the less substituted end of the allyl fragment, are available from allyl halides and trimethylsilylmetal reagents13. 2-Chloro-l-cyclohexenes react with inversion of configuration and a 1,3-shift, with better results in the presence of coppcr(l) iodide14. 

Allylsilanes are available by treatment of allyl acetates and allyl carbonates with silyl cuprates17-18, with antarafacial stereochemistry being observed for displacement of tertiary allyl acetates19. This reaction provides a useful asymmetric synthesis of allylsilanes using esters and carbamates derived from optically active secondary alcohols antarafacial stereochemistry is observed for the esters, and suprafacial stereochemistry for the carbamates20,21. 

An iinportanl advance in this synthesis of allylsilanes involved the use of optically active palladium ferrocenyl complexes as catalysts to provide optically active allylsilanes with good enantiomeric excesses being obtained for (/. (-allylsilanes and less good enantiomeric excesses for (Z)-allylsilanes26,27. 

Allylsilanes have been prepared using Wittig condensations28,29. 

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