Asymmetric terminal olefin

Asymmetric epoxidation of terminal olefins has remained problematic, despite the general success of the novel dioxirane-based catalysts. The enantiomeric excesses in these reactions do not usually exceed 85% (see Section 9.1.1.1). As recrystallization of epoxides can be complicated, enantiopure terminal epoxides are difficult to obtain. 

It is well documented that hydrosilylation of alkyl-substituted terminal olefins catalyzed by transition metal complexes proceeds with high regioselectivity in giving linear hydrosilylation products which do not possess a stereogenic carbon center.2 It follows that the asymmetric synthesis by use of the hydrosilylation of alkyl-substituted... 

As mentioned above, we planned to obtain optically pure styrenyl ethers through Zr-catalyzed kinetic resolution [5] subsequent metal-catalyzed rearrangement would afford optically pure chromenes. However, as shown in Scheme 11, the recovered starting material (40) was obtained with <10% ee (at 60% conversion) upon treatment with 10 mol% (,R)-(EBTHI)Zr-binol (3b) and five equivalents of EtMgCl (70°C, THF). We conjectured that, since the (EBT-HI)Zr-catalyzed reaction provides efficient resolution only when asymmetric alkylation occurs at the cyclic alkene site, competitive reaction at the styrenyl terminal olefin renders the resolution process ineffective. Analysis of the H NMR spectrum of the unpurified reaction mixture supported this contention. Indeed, as shown in Scheme 11, catalytic resolution of disubstituted styrene 49... 

Collman et al.99 reported the asymmetric epoxidation of terminal olefins catalyzed by iron porphyrin complex 129. The catalyst was synthesized by connecting binaphthyl moieties to a readily available aa/ / -tetrakis(aminophenyl)-porphyrin (TAPP). Epoxidation of unfunctinalized olefins was carried out using iodosylbenzene as the oxidant. As shown in Scheme 4-46, excellent results were... 

Catalytic asymmetric hydrosilylation of prochiral olefins has become an interesting area in synthetic organic chemistry since the first successful conversion of alkyl-substituted terminal olefins to optically active secondary alcohols (>94% ee) by palladium-catalyzed asymmetric hydrosilylation in the presence of chiral monodentate phosphine ligand (MOP, 20). The introduced silyl group can be converted to alcohol via oxidative cleavage of the carbon-silicon bond (Scheme 8-8).27... 

In addition to the enantioselective epoxidation of trans- and trisnbstitnted olefins, efforts have also been made for the asymmetric epoxidation of cis- and terminal olefins. Glncose-derived ketone 55 was reported to be a highly enantioselective catalyst for the epoxidation of varions cw-olefins and certain terminal olefins (Fig. 11, Table 4) [97-100]. The resnlts of epoxidation with ketone 55 indicate that a n... 

Previously, some fluorocyclohexanones were used in a catalytic amount with Oxone for asymmetric epoxidation reaction, but they gave a poor ee . It was found later that chiral ketones derived from fructose work well as asymmetric epoxidation catalysts and show high enantioselectivity in reactions of /rani-disubstituted and trisubsti-tuted olefins ". Cis and terminal olefins show low ee under these reaction conditions. Interestingly, the catalytic efficiency was enhanced dramatically upon raising the pH. Another asymmetric epoxidation was also reported using Oxone with keto bile acids. ... 

In conclusion, the chiral salen Co(III) complexes immobilized on Si-MCM-41 colud be synthesized by multi-grafting method. The asymmetric synthesis of diols from terminal olefins was applied with success using a hybrid catalyst of Ti-MCM-41/chiral Co(III) salen complexes. The olefins are readily oxidized to racemic epoxides over Ti-MCM-41 in the presence of oxidants such as TBHP, and then these synthesized diols are generated sequentially by epoxide hydrolysis on the salen Co(lll) complexes. This catalytic system may provide a direct approach to the synthesis of enantioselective diols from olefins. 

Only tethered terminal olefins are reactive, and ring junctures are always formed by coupling to the internal carbon of the multiple bond. If an asymmetric center is present in the tether, the reaction proceeds with high diasteroselectivity. Alkenes with substituents a to the double bond favor trans product formation, whereas fi substituents lead to cis products. 

The asymmetric dihydroxylation of dienes has been examined, originally with the use of NMO as the cooxidant for osmium [56a] and, more recently, with potassium ferricyanide as the cooxidant [56b], Tetraols are the main product of the reaction when NMO is used, but with K3Fe(CN)6, ene-diols are produced with excellent regioselectivity. The example of dihydroxylation of trans.trans-1,4-diphenyl-1,3-butadiene is included in Table 6D.3 (entry 21). One double bond of this diene is hydroxylated in 84% yield with 99% ee when the amounts of K3Fe(CN)6 and K2C03 are limited to 1.5 equiv. each. Unsymmetrical dienes are also dihydroxy-lated with excellent regioselectivity. In these dienes, preference is shown for (a) a bans over a cis olefin, (b) the terminal olefin in a,p,y,8-unsaturated esters, and (c) the more highly substituted olefin [56b],... 

Catalytic asymmetric hydrosilylation of terminal olefins has been developed, using palladium coordinated to the novel binaphthyl ligands (MOP). In all cases (MOPa-d), the enantioselectivity is excellent ( 90% e.e.). The products can be converted into the corresponding secondary alcohols with retention of configuration446. 

TABLE 10.6 Asymmetric Epoxidation of Representative c/s- and Terminal Olefins by Ketone 16 ... 

Asymmetric hydrosilylation of 2-phenyl-1-butene yields enantiomeric excess ee) values as high as 68% [149]. Products obtained by sequential cyclization/ silylation reactions of 1,5-dienes and 1,6-dienes feature in the suggested mechanistic scenario (Scheme 8) [149, 155]. Furthermore, hydrosilylation of terminal olefins achieved both excellent chemoselectivity in the presence of any internal olefin, and functional-group compatibility with halides, ethers, and acetals [155]. 

Arrington, M. P., Bennani, Y. L., Gobel, T., Walsh, P., Zhao, S. H., Sharpless, K. B. Modified cinchona alkaloid ligands improved selectivities in the osmium tetroxide catalyzed asymmetric dihydroxylation (AD) of terminal olefins. Tetrahedron Lett. 1993, 34, 7375-7378. 

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