In osmylation

Unfortunately, the fast rates of 0s04 addition to most alkenes preclude the observation of D/A complexes, and they are not readily characterized. However, a variety of aromatic electron donors form similar (colored) D/A complexes with Os04 that are more persistent and the observation of ArH/ 0s04 complexes forms the basis for examining the electron-transfer paradigm in osmylation reactions. 

Furthermore, kinetic analysis of the decay rate of anthracene cation radical, together with quantum yield measurements, establishes that the ion-radical pair in equation (76) is the critical reactive intermediate in osmylation reaction. Subsequent rapid ion-pair collapse then leads to the osmium adduct with a rate constant k 109 s 1 in competition with back electron-transfer, i.e.,... 

Asymmetric osmylation of alkenes.3 In the presence of 1 equiv. each of 1 and 0s04, alkenes undergo highly enantioselective ris-dihydroxylation. Highest enantiofacial selectivity (90-99%) is shown in osmylation of trans-di- and trisub-... 

It is a consequence of the unusual structure of these complexes in both the solid (dimer) and solution (monomer) states that the IR and Raman spectra show v(0s=0) frequencies to be higher than in osmyl complexes.519,545 In particular the IR band assigned to vas(OsOz) lies near 890 cm 1 in all these oxo esters containing Os L units rather than the 830 cm-1 absorption typical of those containing OsL2 or Os(L) units such behaviour is more typical461 of cis rather than of trans dioxo complexes. 

Figure 25,4 Proposed t bonding in osmyl complexes (a) 3-cemre tz bond formed by overlap of ligand p, and metal dj, orbitals (a similar bond is produced by p, and dj overlap), and (b) MO diagram (see text).

Scheme 8.20. (a) Kishi model for acyclic control in osmylation reactions [90]. (b) Double diastereoselectivity in an AD reaction [92],... 

The most important members of this class are the osmium nitrido, and the osmyl complexes. The reddish-purple K2[OsNCl5] mentioned above is the result of reducing the osmiamate. The anion has a distorted octahedral structure with a formal triple bond Os=N (161pm) and a pronounced /ram-influence (pp. 1163-4), i.e. the Os-Cl distance trans to Os-N is much longer than the Os-Cl distances cis to Os-N (261 and 236 pm respectively). The anion [OsNCls] also shows a rram-effect in that the Cl opposite the N is more labile than the others, leading, for instance, to the formation of [Os NCl4] , which has a square-pyramidal structure with the N occupying the apical position. 

The axial O-An bonds are clearly very strong. They cannot be protonated and are nearly always shorter than the equatorial bonds. In the case of U02 ", for instance, it is likely that the U 0 bond order is even greater than 2, since the U-O distance is only about 180 pm in spite of the difference in the ionic radii of the metal ions (U = 73 pm. Os " = 54.5 pm), this is close to that of the 0s=0 double bond found in the isostructural, osmyl group (175 pm, see p. 1085). It is usually assumed that combinations... 

The interest in asymmetric synthesis that began at the end of the 1970s did not ignore the dihydroxylation reaction. The stoichiometric osmylation had always been more reliable than the catalytic version, and it was clear that this should be the appropriate starting point. Criegee had shown that amines, pyridine in particular, accelerated the rate of the stoichiometric dihydroxylation, so it was understandable that the first attempt at nonenzymatic asymmetric dihydroxylation was to utilize a chiral, enantiomerically pure pyridine and determine if this induced asymmetry in the diol. This principle was verified by Sharpless (Scheme 7).20 The pyridine 25, derived from menthol, induced ee s of 3-18% in the dihydroxylation of /rcms-stilbene (23). Nonetheless, the ee s were too low and clearly had to be improved. 

These compounds give characteristic osmyl IR bands (840 cm 1 in 0s02Cl2(PPh3)2) [151]. 

Annual Volume 71 contains 30 checked and edited experimental procedures that illustrate important new synthetic methods or describe the preparation of particularly useful chemicals. This compilation begins with procedures exemplifying three important methods for preparing enantiomerically pure substances by asymmetric catalysis. The preparation of (R)-(-)-METHYL 3-HYDROXYBUTANOATE details the convenient preparation of a BINAP-ruthenium catalyst that is broadly useful for the asymmetric reduction of p-ketoesters. Catalysis of the carbonyl ene reaction by a chiral Lewis acid, in this case a binapthol-derived titanium catalyst, is illustrated in the preparation of METHYL (2R)-2-HYDROXY-4-PHENYL-4-PENTENOATE. The enantiomerically pure diamines, (1 R,2R)-(+)- AND (1S,2S)-(-)-1,2-DIPHENYL-1,2-ETHYLENEDIAMINE, are useful for a variety of asymmetric transformations hydrogenations, Michael additions, osmylations, epoxidations, allylations, aldol condensations and Diels-Alder reactions. Promotion of the Diels-Alder reaction with a diaminoalane derived from the (S,S)-diamine is demonstrated in the synthesis of (1S,endo)-3-(BICYCLO[2.2.1]HEPT-5-EN-2-YLCARBONYL)-2-OXAZOLIDINONE. 

Organometals and metal hydrides as electron donors in addition reactions 245 Oxidative cleavage of carbon-carbon and carbon-hydrogen bonds 253 Electron-transfer activation in cycloaddition reactions 264 Osmylation of arene donors 270... 

Thermal osmylation. Upon standing in the dark, the purple CT color of anthracene complex [ANT, 0s04] slowly diminishes to afford the 1 2 (insoluble) osmium adduct as the sole product, i.e.,... 

Photochemical osmylation. The irradiation of the charge-transfer bands (Fig. 13) of the EDA complex of 0s04 with various benzenes, naphthalenes, anthracenes, and phenanthrene yields the same osmylated adducts as obtained in the thermal reactions. For example, irradiation of the purple solution of anthracene and 0s04 in dichloromethane at k > 480 nm yields the same 2 1 adduct (B) together with its syn isomer as the sole products, i.e.,... 

Note that the charge-transfer irradiation of the same anthracene/Os04 complex in hexane solution yields only a small amount of the adduct (B) together with considerable amounts of anthraquinone. The latter probably arises from osmylation at the (9,10) positions followed by decomposition of the unstable osmium adduct.218... 

The identical stoichiometries and the color changes that are observed in thermal and photochemical aromatic osmylations point to the ion-radical pair Ar+, OsO T as the seminal intermediate in both activation processes. It is similarly possible that the osmylation of olefinic donors may proceed via the same types of reactive intermediates as delineated for the aromatic osmylation. 

The olive-green osmium(VI) octaethylporphyrin complex 0s02(0EP) (IR i/(Os—O) 825 cm-1) is representative of a number of osmyl porphyrins [185] they can readily be transformed into a number of osmium porphyrins in lower oxidation states (Figure 1.73). 

The history of asymmetric dihydroxylation51 dates back 1912 when Hoffmann showed, for the first time, that osmium tetroxide could be used catalytically in the presence of a secondary oxygen donor such as sodium or potassium chlorate for the cA-dihydroxylation of olefins.52 About 30 years later, Criegee et al.53 discovered a dramatic rate enhancement in the osmylation of alkene induced by tertiary amines, and this finding paved the way for asymmetric dihydroxylation of olefins. 

Dihydroxylation. The key step in the synthesis of a natural mycotoxin from the dehydropentacyclic precursor 1 requires dihydroxylation of the nuclear double bond. Direct osmylation with catalytic 0s04 and N-methylmorpholine N-oxide... 

Ring A diosterols.3 The ring A diosterols (3 and 4) of triterpenes can be prepared from the A2-alkene (1) by osmylation to form the two possible cis-diols (2), which on Swern oxidation give the a-diketone (3). The same diketone is also obtained by Swern oxidation of the 2(3,3a-diol, the product of peracid oxidation followed by acid cleavage. The diketone 3 rearranges to the more stable diosphenol (4) in the presence of base. 

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