Chiral compounds olefins

Since double bonds may be considered as masked carbonyl, carboxyl or hydroxymethylene groups, depending on whether oxidative or reductive methods are applied after cleavage of the double bond, the addition products from (E)-2 and carbonyl compounds can be further transformed into a variety of chiral compounds. Thus, performing a second bromine/lithium exchange on compound 4, and subsequent protonation, afforded the olefin 5. Ozonolysis followed by reduction with lithium aluminum hydride gave (S)-l-phenyl-l,2-ethanediol in >98% ee. 

Synthesis of optically pure compounds via transition metal mediated chiral catalysis is very useful from an industrial point of view. We can produce large amounts of chiral compounds with the use of very small quantities of a chiral source. The advantage of transition metal catalysed asymmetric transformation is that there is a possibility of improving the catalyst by modification of the ligands. Recently, olefinic compounds have been transformed into the corresponding optically active alcohols (ee 94-97%) by a catalytic hydroxylation-oxidation procedure. 

Chiral compounds 91a and 91b, as shown in Table 4-15, were first reported by Jacobsen et al.55 for the asymmetric dihydroxylation of olefins. These catalysts can be used for asymmetric dihydroxlation of a variety of substrates. 

In addition to providing a novel approach to the preparation of chiral compounds, this type of chemistry may allow one to inquire into the subtle stereochemical details of some crystal-state reactions. For example, what are the approach geometry and the preferred side of attack in the addition of bromine to a chiral olefin (259) What can be learned of the geometry of the labile electronically excited species involved in (2 + 2) photocycloaddition reactions (260) ... 

Chiral compounds (Continued) epoxy alcohols, 141 formulas, xiii xvii hydroxystannanes, 318 liquid crystals, 350 molecular lattics, 347 natural, 1 NMR spectra, 282 olefins, 173 oxetanones, 326 phenols, 287 see also Binaphthol phenylbutenes, 172 protonating agents, 324 sulfoxides, 159 sulfur ylides, 328 synthesis, I... 

The Michael-type addition reaction of a carbonucleophile with an activated olefin constitutes one of the most versatile methodologies for carbon-carbon bond formation [1]. Because of the usefulness of the reaction as well as the product, many approaches to the asymmetric Michael-type addition reactions have been reported, especially using chirally modified olefins [2-8]. However, the approach directed towards the enantioselective Michael-type addition reaction is a developing area. In this Chapter, the recent progress of the enantioselective Michael-type addition reaction of active methylene compounds and also organometallic reagents with achiral activated olefins under the control of an external chiral ligand or chiral catalysts will be summarized [9]. 

This work may be regarded as a major breakthrough in asymmetric synthesis and should pave the way for the synthesis of a variety of biologically active chiral compounds because epoxides are versatile building blocks that are commercially produced by the relatively cheap direct air oxidation of unfunctional olefins. 

Hoveyda, Schrock, and coworkers [19] reported using chiral cross-linking compounds immobilized on heterogeneous polystyrene resins. The chiral moiety was then used as a ligand in asymmetric catalyses. In one application, they used the material to prepare a recyclable chiral molybdenum olefin metathesis catalyst that was used in enantioselective ring opening and ringclosing metathesis reactions. The material can be illustrated as follows ... 

Chiral epoxides are extensively employed high-value intermediates in the synthesis of chiral compounds due to their ability to react with a broad variety of nucleophiles. In recent years a lot of research has been devoted to the development of catalytic methods for their production [551, 1141], The Katsuki-Sharpless method for the asymmetric epoxidation of allylic alcohols [1142,1143] and the asynunetric dihydroxylation of alkenes are now widely applied and reliable procedures. Catalysts for the epoxidation of nonfunctionalized olefins have been developed more recently [555, 1144]. Although high selectivities have been achieved for the epoxidation of cA-alkenes, the selectivities achieved with trans- and terminal olefins were less satisfactory using the latter methods. 

Simple olefins do not usually add well to ketenes except to ketoketenes and halogenated ketenes. Mild Lewis acids as well as bases often increase the rate of the cyclo addition. The cycloaddition of ketenes to acetylenes yields cyclobutenones. The cycloaddition of ketenes to aldehydes and ketones yields oxetanones. The reaction can also be base-cataly2ed if the reactant contains electron-poor carbonyl bonds. Optically active bases lead to chiral lactones (41—43). The dimerization of the ketene itself is the main competing reaction. This process precludes the parent compound ketene from many [2 + 2] cyclo additions. Intramolecular cycloaddition reactions of ketenes are known and have been reviewed (7). 

In recent years the solid-phase hydrosilylation reaction was successfully employed for synthesis of hydrolytically stable surface chemical compounds with Si-C bonds. Of special interest is application of this method for attachment of functional olefins, in particular of acrolein and some chiral ligands. Such matrices can be used for subsequent immobilization of a wide range of amine-containing organic reagents and in chiral chromatography. 

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