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Alkenes, epoxidation transfer hydrogenation

The scope of reactions involving hydrogen peroxide and PTC is large, and some idea of the versatility can be found from Table 4.2. A relatively new combined oxidation/phase transfer catalyst for alkene epoxidation is based on MeRe03 in conjunction with 4-substituted pyridines (e.g. 4-methoxy pyridine), the resulting complex accomplishing both catalytic roles. [Pg.123]

The most widely used method for the preparation of epoxides involves oxidation of an aUcene by a peracid, °° via a direct one-step transfer of an oxygen atom. More highly (alkyl) substituted alkenes react fastest showing that electronic effects are more important than steric effects in this reaction. Steric effects do, however, control the facial selectivity of epoxidation conversely hydrogen-bonding groups, such as OH and NH, can direct the reaction to the syn face. [Pg.604]

The alkene is allowed to react at low temperatures with a mixture of aqueous hydrogen peroxide, base, and a co-solvent to give a low conversion of the alkene (29). These conditions permit reaction of the water-insoluble alkene and minimise the subsequent ionic reactions of the epoxide product. Phase-transfer techniques have been employed (30). A variation of this scheme using a peroxycarbimic acid has been reported (31). [Pg.304]

Heteropoly acids can be synergistically combined with phase-transfer catalysis in the so-called Ishii-Venturello chemistry for oxidation reactions such as oxidation of alcohols, allyl alcohols, alkenes, alkynes, P-unsaturated acids, vic-diols, phenol, and amines with hydrogen peroxide (Mizuno et al., 1994). Recent examples include the epoxidations of alkyl undecylenates (Yadav and Satoskar, 1997) and. styrene (Yadav and Pujari, 2000). [Pg.138]

When the reactant is cyclohexene, in the first step of Scheme 26, the direct hydrogen abstraction for the allylic oxidation (path 1) competes with the electron transfer (from the alkene to the M-oxo complex) for the epoxidation (path 2). Because the manganese complex is more readily reduced than the chromium... [Pg.160]

Direct phase-transfer catalysed epoxidation of electron-deficient alkenes, such as chalcones, cycloalk-2-enones and benzoquinones with hydrogen peroxide or r-butyl peroxide under basic conditions (Section 10.7) has been extended by the use of quininium and quinidinium catalysts to produce optically active oxiranes [1 — 16] the alkaloid bases are less efficient than their salts as catalysts [e.g. 8]. In addition to N-benzylquininium chloride, the binaphthyl ephedrinium salt (16 in Scheme 12.5) and the bis-cinchonidinium system (Scheme 12.12) have been used [12, 17]. Generally, the more rigid quininium systems are more effective than the ephedrinium salts. [Pg.537]

See other pages where Alkenes, epoxidation transfer hydrogenation is mentioned: [Pg.125]    [Pg.75]    [Pg.36]    [Pg.50]    [Pg.52]    [Pg.36]    [Pg.52]    [Pg.36]    [Pg.345]    [Pg.201]    [Pg.831]    [Pg.36]    [Pg.423]    [Pg.593]    [Pg.31]    [Pg.3]    [Pg.158]    [Pg.757]    [Pg.651]    [Pg.536]    [Pg.536]    [Pg.223]    [Pg.902]    [Pg.916]    [Pg.55]    [Pg.261]    [Pg.237]    [Pg.160]    [Pg.305]    [Pg.308]    [Pg.425]    [Pg.385]    [Pg.432]    [Pg.449]    [Pg.1137]   
See also in sourсe #XX -- [ Pg.89 ]



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1,2-Epoxides, hydrogenation

Alkene epoxidations

Alkenes epoxidation

Alkenes hydrogenation

Alkenes transfers

Epoxides alkene epoxidation

Hydrogen alkene epoxidation

Hydrogen epoxidation

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