Cyclic olefins, oxidative cleavage

Olefins Oxidative Cleavage Photoirradiation (>280 nm) to an acetonitrile solution containing various cyclic and linear olefins with mesoporous silica containing isolated Ti-oxide species produces the corresponding epoxide with high selectivity (>98 %) [2]. 

Ozonolysis of cyclic olefins in the presence of carbonyl compounds gives the corresponding cross-ozonides.1329 In the ozonation of 1,2,4,5-tetramethyl-1,4-cyclohexadiene, oxidative dehydrogenation (formation of 1,2,4,5-tetramethylben-zene) was found to compete with oxidative cleavage because of steric hindrance.1330 Secondary ozonides (the 76 1,2,4-trioxolanes) are formed in high yields in the gas-phase, low-temperature ozonation of terminal and disubstituted alkenes.1331... 

The tandem 0s04-catalyzed oxidative cleavage of olefin 269 with Oxone as the co-oxidant and sequential direct oxidation of intermediate aldehyde in alcoholic media led to cyclic keto lactone 270 in 45% yield (Equation 34) <20030L3089>. Similar oxidative cyclization with KMnCT-GuSITr resulted in 32% yield of 270 <1994T11709>. 

Koreeda and Hamann have reported the use of silyl tethers in stereocontrolled syntheses of branched-chain 1,4-diols and 1,5-diols [61]. Exposure of (bromomethyl)silyl ethers prepared from the corresponding homoallylic alcohols with Bu SnH in the presence of AIBN allowed smooth conversion to the corresponding cyclic siloxanes, from which diol products were obtained using standard, oxidative cleavage protocols. While monosubstituted olefin 149 selectively underwent 1-endo cyclization, di- and trisubsti-tuted olefins 150 and 151 preferentially reacted through the 6-exo mode with complete stereocontrol, affording the diol products 152 and 153, respectively (Scheme 10-50). 

The same system was used for the direct oxidation of cyclohexene to adipic acid, by oxidation with 4 equiv. of 30% aq. H2O2, via the initial formation of cyclohexene oxide (Fig. 7.5). It was further shown that the methodology is apphcable to the oxidative cleavage of a range of cyclic olefins. ... 

The physical and chemical properties of the X -phosphorins 118 and 120 are comparable to those of phosphonium ylids which are resonance-stabilized by such electron-pulling groups as carbonyl or nitrile substituents Thus they can be viewed as cyclic resonance-stabilized phosphonium ylids 118 b, c, d). As expected, they do not react with carbonyl compounds giving the Wittig olefin products. However, they do react with dilute aqueous acids to form the protonated salts. Similarly, they are attacked at the C-2 or C-4 positions by alkyl-, acyl- or diazo-nium-ions Heating with water results in hydrolytic P—C cleavage, phosphine oxide and the hydrocarbon being formed. 

Ring cleavage of cyclic silyloxy olefins 158 using the oxidative conditions developed by Tamao efficiently afforded the corresponding cA-olefinic dihydroxy compounds 289 in good to excellent yield (Equation 52) <1997TL4757>. 

C-C cleavage of strained rings and ketones has been used to develop useful catalytic reactions. For example, vinylcyclopropanes and vinylcyclobutanes react with alkynes (Equation 6.66) to generate products from 5+2 and 6+2 addition processes that form seven- and eight-membered ring products by overall transformations that are homologs of the Diels-Alder reaction. " The mechanism of these catalytic reactions continues to be studied, but these reactions most likely occur by coordination of the olefin to rhodium and insertion of the metal into the cyclopropene or cyclobutane. Decarbonylation of dialkyl ketones, including relatively unstrained cyclic ketones, has been reported and most likely occurs by oxidative addition into the acyl-alkyl C-C bond, subsequent de-insertion of CO, and C-C reductive elimination. 

---