Alkenes stereoselective epoxidation

Epoxidation of Acyclic Alkenes. Stereoselective epoxidation of a series of allylic carbamate methyl esters (eq 34), homoallylic alcohols (eq 35), and acetates (eq 36) could be performed with good to excellent stereocontrol. It is believed that the directing effect of the carbamate protecting group plays an important role in dictating the level of stereocontrol. 

A new stereoselective epoxidation catalyst based on a novel chiral sulfonato-salen manganese(III) complex intercalated in Zn/Al LDH was used successfully by Bhattacharjee et al. [125]. The catalyst gave high conversion, selectivity, and enantiomeric excess in the oxidation of (i )-limonene using elevated pressures of molecular oxygen. Details of the catalytic activities with other alkenes using both molecular oxygen and other oxidants have also been reported [126]. 

Preparation of nonracemic epoxides has been extensively studied in recent years since these compounds represent useful building blocks in stereoselective synthesis, and the epoxide functionality constitutes the essential framework of various namrally occurring and biologically active compounds. The enantiomericaUy enriched a-fluorotropinone was anchored onto amorphous KG-60 silica (Figure 6.6) this supported chiral catalyst (KG-60-FT ) promoted the stereoselective epoxidation of several trans- and trisubstituted alkenes with ees up to 80% and was perfectly reusable with the same performance for at least three catalytic cycles. 

NR = nonreactive toward hydrocarbons PO = oxidation of phosphines to phosphine oxides MF — peroxometallacyclic adduct formation with cyanoalkenes NSE — nonstereoselective epoxidation SE=stereoselective epoxidation AE = asymmetric epoxidation HA- hydroxylation of alkanes HB=hydroxylation of arenes OA = oxidation of alcohols to carbonyl compounds K = ketonization of Lermina 1 alkenes SO oxidation of S02 to coordinated S04 MO = metallaozonide formation with carbonyl compounds I = oxidation of isocyanides to isocyanates. 

Molecular-orbital calculations indicate that the stereoselective epoxidation of the alkene 192 by peroxy acids arises from stereoelectronic control exerted by a CF3— C bond orientated anti to the alkene plane, in contrast to the previously proposed model for epoxidation of allylic fluoride in which the F—C bond and alkene bonds are in a syn arrangement305. 

Many oxo-metal complexes efficiently epoxidize alkenes. Stereoselectivity in these epoxidations is most often achieved by precoordination of functional groups in the substrates. If the metallic centers are embedded in a chiral environment that allows stereoselectivity to rely solely on nonbonded interactions, enantioselective epoxidation may be extended to nonfunctionalized alkenes16. 

Periodate compounds have been used for the epoxidation of simple olefins too (MIO4, MH4O6, or M2H3IO6 M = Li, Na, K, Rb, Cs, etc.). In alkaline medium, xenon-trioxide epoxidizes alkenes stereoselectively there is no c/s-hydroxylation as when other inorganic oxides are employed. ... 

Thallium triacetate, TI(0C0CH3)3 1.5H20 (mp 182 C), like the monoacetate, is used for the stereoselective acetoxylation of alkenes [411] and for oxidations of alkenes to epoxides [412]. 

NR s not reactive toward hydrocarbons S = stereoselective epoxidation E = epoxidation HA = hydroxylation of alkanes OA = oxidation of alcohols to carbonyl compounds PO oxidation of phosphines to phosphine oxides OC = oxidative cleavage of alkenes K= ketonization of alkenes DO = hydroxylation of alkenes to diols AO al1ylic oxidation of alkenes. 

Stereoselectivity. Epoxidation involves an electrophilic yyn-addition of the oxygen moiety of the peroxy acid to the double bond. The concerted formation of two new C-0 bonds ensures that the reaction is stereospecific cA-alkenes furnish the corresponding cA-epoxides and trans-alkenes the corresponding trans-isomers (racemic). 

Stereoselective epoxidation of alkenes, desymmetrization of maso-TV-sulfonylaziri-dines, Baeyer-Villiger oxidation of cyclobutanones, Diels-Alder reactions of 1,2-dihydropyridines, and polymerization of lactides using metal complexes of chiral binaphthyl Schiff-base ligands 03CCR(242)97. 

The first example of the immobilization of a chiral ketone to promote the enan-tioselective epoxidation of alkenes with Oxone has been reported by Sartori and coworkers [322]. They anchored a-fhiorotropinone on KG-60 silica, MCM-41 and a Merrifield resin. The catalysts were tested for the epoxidation of 1-phenylcyclo-hexene but the polymer-supported fhiorotropinone 121 showed a low activity and selectivity. The catalyst immobilized on inorganic supports promoted the stereoselective epoxidation of alkenes with ee values up to 80% and could be reused with the same performance for three runs. 

Epoxidation. Oxone is used to generate dioxirane from a ketone added to the reaction medium. Such dioxiranes epoxidize alkenes stereoselectively. 2-Cyclo-hexenol gives two epoxy alcohols in a ratio of 77 23 (trans cis). 

Diaminocyclohexane [(R,R)- and ( S, S)-enantiomer] forms an imine (SCHIFF base) with 2,5-di-/ rr-butylsalicylaldehyde, which gives a chiral Mn(III) (salen) complex with Mn(II)acetate and oxygen. In contrast to the Sharpless-Katsuki protocol (p 20), this complex effects the stereoselective oxygen transfer (from oxidants, e.g. monopersulfate or NMO) to unfunctionalized alkenes (Jacobsen epoxidation [1], extended by Katsuki [2]) giving rise to enantiomeric oxiranes with 90-98% ee. 

Theoretical consideration of stereoselective epoxidation with oxoiron porphyrins has lead to the remarkable conclusion that oxygen is inserted into the iron-nitrogen bond and the alkene is coordinated in a perpendicular orientation with respect to the iron-oxygen bond [64]. 

Ph3Si ethylene oxide catalytically adds PhSH to give a- and -adducts in 6 1 ratio, and serves as a vinyl dication equivalent with RCu to give alkenes stereoselectively, while epoxides rearrange in the presence of silylated nucleophiles Diphenylmethylsilylation of cyclopropane carboxylates gives the C-silylated ester which then form C-silylated cyclopropyl ketones, P-silyl cyclopropyl carbinols, and alkylidene cyclopropancs, which ring expand to the... 

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