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Stereospecific reactions metallation

In general, reductive removal of a sulphonyl group from vinyl sulphones is not a stereospecific reaction. However, two methods, both developed by Julia, result in stereospecific products. The first one involves reaction of the vinyl sulphone with n-BuMgCl in the presence of a transition metal catalyst such as Ni(acac)2. This method was used to synthesize a pheromone having a (Z, )-diene (equation 27)59. Palladium catalysts can also be used for... [Pg.375]

We also mentioned stereospecificity of metal-catalyzed reactions inside zeolite cavities. In acid catalysis by zeolites it is well known that shape selectivity can be imposed by (1) selective admission of reactants fitting into zeolite pores, (2) selective release of products able to diffuse through zeolite channels, while larger molecules are retained, and (3) transition state selectivity, favoring, e.g., a monomolecular transition state over a bimolecular state in a narrow cavity. New tools that have conceptually been added to this arsenal include the collimation of molecules diffusing through well-defined pores, which then hit an active site preferentially via one particular atom or group. [Pg.209]

Reaction with Alkynes. The silyl cuprate reacts with alkynes by syn stereospecific metallo-metallation (eq 3). Provided that the cuprate is derived from copper cyanide, the regioselectivity with terminal alkynes is highly in favor of the isomer with the sUyl group on the terminus. The intermediate vinyl cuprate (3) reacts with many substrates, familiar in carbon-based cuprate chemistry, to give overall syn addition of a silyl group and an electrophile to the alkyne. A curious feature of this reaction is that the intermediate (3), although uncharacterized, has the stoichiometry of a mixed silicon-carbon cuprate, and yet it transfers the carbon-based group to most substrates, in contrast to the behavior of mixed silyl alkyl cuprates. [Pg.351]

The converse situation in which ring closure is initiated by the attack of a carbon-based radical on the heteroatom has been employed only infrequently (Scheme 18c) (66JA4096). The example in Scheme 18d begins with an intramolecular carbene attack on sulfur followed by rearrangement (75BCJ1490). The formation of pyrrolidines by intramolecular attack of an amino radical on a carbon-carbon double bond is exemplified in Scheme 19. In the third example, where cyclization is catalyzed by a metal ion (Ti, Cu, Fe, Co " ), the stereospecificity of the reaction depends upon the choice of metal ion. [Pg.100]

The remarkable stereospecificity of TBHP-transition metal epoxidations of allylic alcohols has been exploited by Sharpless group for the synthesis of chiral oxiranes from prochiral allylic alcohols (Scheme 76) (81JA464) and for diastereoselective oxirane synthesis from chiral allylic alcohols (Scheme 77) (81JA6237). It has been suggested that this latter reaction may enable the preparation of chiral compounds of complete enantiomeric purity cf. Scheme 78) ... [Pg.116]

In the past few years metal deuterides have become commercially available at reasonable prices. This has encouraged the use of these reagents for reactions involving deuteride displacements of suitable leaving groups. The attractive feature of these reactions is the stereospecificity of the deuterium insertion. [Pg.196]

A facile method for the stereospecific labeling of carbon atoms adjacent to an oxygenated position is the reductive opening of oxides. The stereospecificity of this reaction is due to virtually exclusive diaxial opening of steroidal oxides when treated with lithium aluminum hydride or deuteride. The resulting /ra/w-diaxial labeled alcohols are of high stereochemical and isotopic purity, with the latter property depending almost solely on the quality of the metal deuteride used. (For the preparation of m-labeled alcohols, see section V-D.)... [Pg.204]

Solutions of alkali metals in liquid ammonia have been developed as versatile reducing agents which effect reactions with organic compounds that are otherwise difficult or impossible/ Aromatic systems are reduced smoothly to cyclic mono- or di-olefins and alkynes are reduced stereospecifically to frani-alkenes (in contrast to Pd/H2 which gives cA-alkenes). [Pg.79]

The observation that addition of imidazoles and carboxylic acids significantly improved the epoxidation reaction resulted in the development of Mn-porphyrin complexes containing these groups covalently linked to the porphyrin platform as attached pendant arms (11) [63]. When these catalysts were employed in the epoxidation of simple olefins with hydrogen peroxide, enhanced oxidation rates were obtained in combination with perfect product selectivity (Table 6.6, Entry 3). In contrast with epoxidations catalyzed by other metals, the Mn-porphyrin system yields products with scrambled stereochemistry the epoxidation of cis-stilbene with Mn(TPP)Cl (TPP = tetraphenylporphyrin) and iodosylbenzene, for example, generated cis- and trans-stilbene oxide in a ratio of 35 65. The low stereospecificity was improved by use of heterocyclic additives such as pyridines or imidazoles. The epoxidation system, with hydrogen peroxide as terminal oxidant, was reported to be stereospecific for ris-olefins, whereas trans-olefins are poor substrates with these catalysts. [Pg.202]

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See also in sourсe #XX -- [ Pg.291 ]



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Stereospecific reactions

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