Silicon compounds allylsilane

Allylchlorosilanes undergo Friedel-Crafts alkylation with aromatic compounds such as benzene derivatives and ferrocene to give [p-(chlorosilyl)alkyl]arene compounds in the presence of Lewis acid catalyst. Allylsilanes containing two or more chlorine atoms on silicon react smoothly with benzene under mild conditions to give alkylation products in good yields [Eq. (15)]. In alkylations of benzene, the reactivity of the allylsilanes increases as the number of chlorine atoms on the silicon increases, but decreases as the number of methyl groups increases. Because the reactivity of allylsilanes is sensitive to the electronic nature of the substituents on the silicon atom, allylsilane selection is an important factor for alkylation reactions. 

Tandem (Domino) reactions, in which two or more bond-forming processes result from a single step, are useful for rapid synthesis of complex molecules.138 Functionalized allylsilanes and the related silicon compounds have frequently been used for tandem reactions, because of their ease of synthesis and moderate, controllable reactivity. Recently, much attention has been paid to the use of multifunctional allylsilanes bearing another reactive group on silicon. 

The Lewis acidic character of reactive pentacoordinate silicon compounds has been unequivocally confirmed by Corriu, Sakurai and Hosomi [90]. Allylsilicates prepared from allylsilanes and catechol can undergo allylation reaction with aldehydes in the absence of Lewis acid promoter (Sch. 51). 

Allylsilanes are intrinsically nonnucleophilic. We believe that addition of fluoride ion to an allylsilane forms a silicate anion, which can react at either end of the tc-system. Thus from a mechanistic viewpoint, substitution of an allylsilane under nucleophilic conditions is more appropriately considered an addition-elimination reaction with the terms Se2 and Se2 aptly representing the elimination process. For recent evidence of pentacoordinate silicate intermediates in fluoride ion catalyzed allylation using trimethylallylsilane, see a) M. Kira, M. Kobayashi and H. Sakurai, Tetrahedron Lett.. 28. 4081 (1987) b) M. Kira, K. Sato and H. Sakurai. J. Am. Chem. Soc.. 110, 4599 (1988) c) T. Hayashi, Y. Matsumoto, T. Kiyoi, Y. Ito, S. Kohra, Y. Tominaga and A. Hosomi, Tetrahedron Lett., in press d) H. Sakurai, Lewis Acid Character and Selective Reactions of Pentacoordinate Silicon Compounds, this volume. 

In the case of alkylation using allylsilancs in the presence of aluminum chloride as a catalyst, allylsilanes containing one or more chlorine substituents on the silicon react with aromatic compounds at room temperature or below 0 C to give alkylated products. 2-aryl-1 -silylpropanes.- while allyltrimethylsilane did not give the alkylated product but instead dimerized to give the allylsilylation product.. S-itrimethylsilyli-d-itrimethylsilylrnethyl)- 1-pentene (Eq. (1 )). In the alkylation reaction, the reactivity of allylsilanes increased as the number of chlorine... 

Pyrrolo[l,2-c][l,3]oxazin-l-one 248 has been obtained by reaction of allylsilanes with a pyrrolidine-lV-acyliminium ion 247 (Scheme 32), formed by addition of a Lewis acid on compound 244. The /3-silyl carbocation formed by the reaction with allylsilane 246 reacted with the oxygen of the N-15OC group followed by the loss of 2-methylpropene. The reaction was not very stereoselective when trimethylsilane was used, whereas with larger group on the silicon the selectivity was increased <1997J(P1)2163>. 

In 1982, Sakurai [7] described a catalytic version of this reaction (Scheme 13.4). The addition of small quantities of fluoride anions to the allylsilane 1 generates the pentacoordinated silicon species 10, probably in equilibrium with the starting materials 1 and 11. This activated species can react with the carbonyl derivative 6 to yield the alkoxide 12 which is trapped by fluorotrimethylsilane. This last step not only furnishes the silylated compounds 13 but also regenerates the fluoride catalyst 11. Acidic work-up then leads to the desired homoallylic alcohol 7. 

Hwu et al. have examined the dependence of the metal oxidant on the mode of reactivity in silicon-controlled allylation of 1,3-dioxo compounds [95JOC856]. The use of manganese(III) acetate furnished the dihydrofuran product 22 only. On the other hand, use of cerium(IV) nitrate resulted in the formation of both acyclic (23) as well as the cyclized compound, with the product distribution dependent on the nature of the allylsilane. Facile synthesis of dihydrofurans by the cerium(IV) mediated oxidative addition of 1,3-dicarbonyl compounds to cyclic and acyclic alkenes has also been reported [95JCS(P1)187]. 

There has been much interest in the chemistry of the trimethylsilyl group in the last few decades. This has led to many methodologies for the introduction of this group into organic compounds and a particularly good review on allylsilane chemistry has been published recently380. Probably the most important method of introducing a new carbon-silicon... 

In this sub chapter the most important synthetic aspect of the RCM of unsaturated organosilicon compounds will be discussed. For a general review on RCM see Refs. [59,122-124]. For a review on RCM of silyl dienes see Refs. [6,7]. A number of valuable synthetic applications have been proposed over the last few years. As follows from the data available, from the point of view of the application of RCM of vinyl and allylsilanes, the most important are silicon-tethered processes. For a general review on the silicon tethered processes see Refs. [125,126],... 

Allylsilanes are known as interesting and useful reagents for organic synthesis.85-88 Hurd first reported the direct reaction of elemental silicon with allyl chloride in the presence of copper catalyst to give a mixture of allylchlorosilanes and polymeric materials.15 Among the volatile compounds, allyltrichlorosilane, formed by the 1 1 1 reaction of allyl chloride, hydrogen chloride and elemental silicon, was observed as the major product instead of the normally expected diallyldichlorosilane. Since diallyldichlorosilane thermally polymerizes at temperatures above 130°C, the product mixture polymerized during the reaction or upon distillation. 

The addition of an allylsilane to an electrophile was first documented in 1948 by Sommer et al. [6]. These workers predicted that the allylsilane would react with an electrophile to generate a silicon-stabilized cationic intermediate. In 1956, Galas and co-workers demonstrated that allylsilanes undergo an allylic shift in the protiodesilylation of a cyclohexenylsilane to afford a methylidenecyclohexane [7], The first report of the reaction of allylsilanes with carbonyl compounds (1974) is also due to Galas [8]. These authors used activated substrates such as perfluoro-acetone and chloroacetone and AIGI3, GaGl3 or InGl3 as Lewis acids to promote... 

The relative reactivities of organometallics containing group 14 elements are closely associated with the electronegativity and dissociation energy of the M—C bonds of the elements. For example, some organotin compounds such as allylstannanes are easily decomposed to form radical species whereas homolysis of the carbon-silicon bond of allylsilanes is rarely achieved, which reflects the dissociation energy of the respective M—C bonds. 

Carbanions a to silicon are stabilized by the overlap of the filled 2p orbital on carbon with the vacant antibonding orbital of carbon-silicon bond ((a -p)K conjugation) (Scheme 1 A). For example, the a-carbanions of allylsilanes or similar compounds are easily generated by base removal of a proton (eq (9)) [6]. 

Since the preparation of anionic species or organosilicon compounds is largely restricted by its reaction conditions, the synthetic utility of silyl anions for the synthesis of organosilicon compounds is limited. However silyllithiums possessing one or more phenyl groups on a silicon atom are readily prepared by the reductive metallation of the corresponding halosilanes with lithium. Allylsilanes are synthesized by the reaction of allyl acetates with the cuprate prepared from such a reagent (eq (47)) [43]. 

Acid-induced reactions of silicon-containing unsaturated compounds with A -acyliminium intermediates have proven particularly useful. Allylsilanes lead to the corresponding allyl-substituted products. This reaction proceeds well even for -lactams (equation 49). 5.86 j, g penicillin-derived 4-acetoxyazet-idinone (91) reacts with excess allylsilane in refluxing dichloroethane, catalyzed by TMSOTf, to produce as the sole product trans compound (92). A -Acyliminium ions generated from cyclic ureas and carbamates (93) likewise yield allylated products with virtually complete trans stereoselectivity (equation SO). Allylstannanes react under somewhat milder conditions than allylsilanes, requiring only a catalytic amount of BFsZ EtjO at room temperature for a 3-lactam system (equation 51). This allylstannane procedure was applied to cyclic carbamate systems for the stereoselective synthesis of several isomers of statine. Thus, ethoxycarbamate (94) reacts with methallyltributylstannane in excellent yield and dia-stereoselectivity (equation 52). ... 

Yoshida J, Murata T, Isoe S (1986) Electrochemical oxidation of organosihcon compounds 1. Oxidative cleavage of carbon-silicon bond in allylsilanes and benzylsilanes. Tetrahedron Lett 27 3373-3376... 

ABSTRACT. Pentacoordinate organosilicon species behave as Lewis acid as well as nucleophile. This unique character provides several interesting applications in selective reactions useful for organic synthesis. Accordingly, new reduction of carbonyl compounds with pentacoordinate hydridosilicates, new regio- and enantioselective allylation of aldehydes with pentacoordinate allylsilanes, and the new cleavage reaction of C-Si bonds are discussed. In these reactions, it is demonstrated that unique characters of pentacoordinate silicon species as a Lewis acid play an important role. 

Corriu and his group have synthesized the first stable pentavalent silicon derivative (below). This compound also reacts with aldehydes leading to homoallylic alcohols regio- and stereoselectively via a transition state in which silicon is hexacoor-dinate. It is the coordination of the allyl and aldehyde that generates the regio- and stereoselectivity. In this way, the allylsilane Z leads to the syn isomer (scheme below), whereas the allylsilane E reacts to produce the anti isomer. 

Silicon.— Allylsilanes are outstandingly useful carbon nucleophiles as a result of their ability to react with electrophiles in a controlled and specific manner to form new carbon-carbon bonds. Furthermore, metallation to give a-(trimethyl-silyl)allylic carbanions introduces the possibility of an additional level of control over the mode of attack (either a or y) exhibited by the allylsilane. It is not surprising, therefore, to find the chemistry of these species occupying a prominent position in this year s organosilicon literature, and in addition to the many applications reported some new routes to these compounds have been described. One such example is shown in Scheme 13, in which the starting silyl sulphone is readily prepared by oxidation of the product obtained from reaction of thio-phenol with vinyltrimethylsilane." ... 

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