Alkene complexes, osmium

Doyle MP (2004) Metal Carbene Reactions from Dirhodium(II) Catalysts. 13 203-222 Drudis-Sole G, Ujaque G, Maseras F, Lledds A (2005) Enantioselectivity in the Dihydroxyla-tion of Alkenes by Osmium Complexes. 12 79-107... 

Among oxo-metals, osmium tetroxide is a particularly intriguing oxidant since it is known to oxidize various types of alkenes rapidly, but it nonetheless eschews the electron-rich aromatic hydrocarbons like benzene and naphthalene (Criegee et al., 1942 Schroder, 1980). Such selectivities do not obviously derive from differences in the donor properties of the hydrocarbons since the oxidation (ionization) potentials of arenes are actually less than those of alkenes. The similarity in the electronic interactions of arenes and alkenes towards osmium tetroxide relates to the series of electron donor-acceptor (EDA) complexes formed with both types of hydrocarbons (26). Common to both arenes and alkenes is the immediate appearance of similar colours that are diagnostic of charge-transfer absorp-... 

The stoichiometric enantioselective reaction of alkenes and osmium tetroxide was reported in 1980 by Hentges and Sharpless [17], As pyridine was known to accelerate the reaction, initial efforts concentrated on the use of pyridine substituted with chiral groups, such as /-2-(2-menthyl)pyridine but e.e. s were below 18%. Besides, it was found that complexation was weak between pyridine and osmium. Griffith and coworkers reported that tertiary bridgehead amines, such as quinuclidine, formed much more stable complexes and this led Sharpless and coworkers to test this ligand type for the reaction of 0s04 and prochiral alkenes. 

Chloroxytrifluoromethane, 26 137-139 reactions, 26 140-143 addition to alkenes, 26 145-146 oxidative addition, 26 141-145 vibrational spectra, 26 139 Chloryl cation, 18 356-359 internal force constants of, 18 359 molecular structure of, 18 358, 359 properties of, 18 357, 358 synthesis of, 18 357, 358 vibrational spectra of, 18 358, 359 Chloryl compounds, reactions of, 5 61 Chloryl fluoride, 18 347-356 chemical properties of, 18 353-356 fluoride complexes of, 5 59 molecular structure of, 18 349-352 physical properties of, 18 352, 353 preparation, 5 55-57 and reactions, 27 176 properties of, 5 48 reactions, 5 58-61, 18 356 synthesis of, 18 347-349 thermal decomposition of, 18 354, 355 vapor pressures, 5 57, 18 353 vibrational spectra of, 18 349-352 Chloryl ion, 9 277 Cholegobin, 46 529 Cholesterol, astatination, 31 7 Cholorofluorphosphine, 13 378-380 h CHjPRj complexes, osmium, 37 274 Chromatium, HiPIP sequence, 38 249 Chromatium vinosum HiPIP, 38 108, 133 Fe4S4 + core, 33 60 Chromato complexes, osmium, 37 287... 

A vincinal amino alcohol grouping is present in a fair number of natural products which possess useful biological activity, such as antibiotics122. Such a functionality has been produced from alkenes via osmium-mediated aminohydroxylation (equation 22)123. The reaction proceeds in 40-97% yield and is enantioselective if chiral osmium-Cinchona alkaloid complexes are used to mediate the reaction. 

Application of computaional methods to the enantioselective dihydroxylations of alkenes by osmium complexes have been reviewed with a special focus on methods used to study the origin of high enantioselectivity. The use of a vast number of computational techniques such as QM, MM, Q2MM, QM/MM, molecular dynamics, and genetic algorithms has been enumerated.98... 

Osmium-catalysed dihydroxylation has been reviewed with emphasis on the use of new reoxidants and recycling of the catalysts.44 Various aspects of asymmetric dihydroxylation of alkenes by osmium complexes, including the mechanism, acceleration by chiral ligands 45 and development of novel asymmetric dihydroxylation processes,46 has been reviewed. Two reviews on the recent developments in osmium-catalysed asymmetric aminohydroxylation of alkenes have appeared. Factors responsible for chemo-, enantio- and regio-selectivities have been discussed.47,48 Osmium tetraoxide oxidizes unactivated alkanes in aqueous base. Isobutane is oxidized to r-butyl alcohol, cyclohexane to a mixture of adipate and succinate, toluene to benzoate, and both ethane and propane to acetate in low yields. The data are consistent with a concerted 3 + 2 mechanism, analogous to that proposed for alkane oxidation by Ru04, and for alkene oxidations by 0s04.49... 

Osmium forms a wide variety of alkyl and aryl complexes including homoleptic alkyl and aryl complexes and many complexes with ancillary carbonyl (see Carbonyl Complexes of the Transition Metals), cyclopentadienyl (see Cyclopenta-dienyl), arene (see Arene Complexes), and alkene ligands (see Alkene Complexes). It forms stronger bonds to carbon and other ligands than do the lighter elements of the triad. Because of this, most reactions of alkyl and aryl osmium complexes are slower than the reactions of the corresponding ruthenium complexes. However, because osmium is more stable in higher oxidation states, the oxidative addition (see Oxidative Addition) of C-H bonds is favored for osmium complexes. The rate of oxidative addition reactions decreases in the order Os > Ru Fe. 

Oxo(/erf-alkylimido)osmium complexes are utilized in the diastereoselective oxyamination and diamination of alkenes. A mechanism involving nucleophilic attack of alkene to osmium and formation of a four-membered cyclic intermediate has been proposed38, but the [3 + 2] cycloaddition mechanism has also been suggested by quantum chemical calculations on models for hex-2-enopyranosides39. 

Bioxazolines have also been employed in the enantioselec-tive dihydroxylation of alkenes with Osmium Tetroxide The best results have been obtained in the dihydroxylation of 1-phenylcyclohexene with a complex, formed between OSO4 and the diisobutylbioxazoline (4) (R=CH2CHMe2>, as a stoichiometric reagent (70% ee). Styrene and trans -stilbene afford enantioselec-tivities below 20% ee under these conditions (for highly enantios-elective dihydroxylation catalysts, see Dihydmquinine Acetate and Osmium Tetroxide). 

Double bonds in the side chains of aromatic compounds undergo hy-droxylation in the same way as those in simple alkenes [784]. With some compounds, such as stilbene, enantioselective hydroxylation can be accomplished with chiral compounds, which, by complexing osmium tetrox-ide, form enantiomeric products in high enantiomeric excesses (equation 83) [951, 1033]. 

The Corey mechanistic proposal is founded on the ability of the alkene substrate to bind between the two quinohne ring walls which are spaced parallel with a separation of 7.2 A. When the substrate binds in this elongated cleft, the alkene complexes to the osmium center in the W-complexated osmium tetroxide through a donor-acceptor (d-Jt) interaction (Scheme 10). The interaction between the alkene and osmium tetroxide is also complemented with favorable van der Waals interactions between the alkene and the binding cleft. These interactions are implied by the Michaelis-Menten kinetics [72] observed in the process. The observation of Michaelis-Menten kinetics in the AD process has however been questioned as an experimental artifact by the Sharpless group [73]. The (3+2) addition takes place between the axial and one of the equatorial oxygen atoms in osmium tetroxide which are in close proximity with the alkene. This represents the minimum motion pathway in the formation of the pentacoordinate os-mium(VI) glycolate ester. In the Corey model the rate acceleration observed in... 

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