Subject carbonyls with alkenes

A wide range of alkenes may be used as substrates. The reaction is most commonly performed with alkenes of normal electronic nature, but electron deficient alkenes, such as a, 3-unsaturated carbonyl compounds, and very electron rich alkenes, such as enol ethers and enamines, have also been used successfully. Not surprisingly, the cyclopropylcarbinyl ethers and amines that are formed in the latter reactions (see Table S) are subject to facile rearrangements. 

The fast reaction of NO3 radicals with alkenes was found to give substantial yields of bifunctional carbonyl-nitroxy products and the mechanism of their formation is expected to be relevant also for the conditions of the troposphere. Studies performed by other workers [12] have shown that such organic nitrates may contribute to the atmospheric transport of NOx by acting as reservoirs, releasing NOx by their degradation in the atmosphere, but bifiinctional nitrates may also be subject to fast removal by wet deposition. 

The epoxidation of electron-deficient alkenes, particularly a,P-unsaturated carbonyl compounds, continues to generate much activity in the literature, and this has been the subject of a recent concise review <00CC1215>. Additional current contributions in this area include a novel epoxidation of enones via direct oxygen atom transfer from hypervalent oxido-).3-iodanes (38), a process which proceeds in fair to good yields and with complete retention of... 

Vinyl substitutions on alkenes not having their double bonds conjugated with carbonyl groups often proceed more rapidly and give better product yields when the reactions are conducted in the presence of an unhindered secondary amine. Conjugated and nonconjugated dienes are usually only minor products in these cases. The major products normally are allylic amines obtained by nucleophilic attack of the secondary amine upon the ir-allylpalladium intermediates. Since allylic amines may be quatemized and subjected to the Hoffmann elimination, this is a two-step alternative to the direct vinyl substitution reaction.90... 

The mechanism of the reaction of ozone with double bonds (equation 68) is very complex and still subject to arguments. An alkene and ozone may first form a it complex (a), which forms a a complex (b), a molo-zonide (c), or both. The molozonide may change to a dipolar ion (d), which breaks down with the fission of the carbon-carbon bond to a carbonyl compound and another dipolar ion (e). The two species recombine to give the ultimate product, ozonide (f) (1,3,4-trioxolane, also known as 1,3,4-trioxacyclopentane) [76], The temporary presence of the carbonyl com-... 

Another variation of the Wittig reaction is the Wittig-Horner reaction, in which the anion generated ot- to phosphine oxide is used as a nucleophile to react with carbonyl compounds. The intermediate formed in this reaction, -hydroxyphosphine oxide, is isolable particularly when bases with lithium counterion are used for deprotonation. Since the j6-hydroxyphosphine oxides are diastereomers, they can be separated and subjected to elimination to form the corresponding alkenes. Since the elimination of phosphonate moiety is syn, stereospecific alkenes are obtained from the elimination step. As expected, the generation of erythro and threo isomers is dependent on the solvent and the reaction conditions. 

Thus far, discussion has centered around the reaction of alkenes with a source of electrophilic oxygen as a route to epoxides [the C=C + O protocol]. However, a second general approach is represented by the reaction of carbonyl compounds with amphophilic carbon centers [the C=0 + C protocol]. For example, sulfonium yhdes are known to convert aldehydes and ketones to epoxides much recent work has focused on asymmetric induction using this methodology, a topic which has been the subject of a concise review in the past year <04ACR611>. As an illustration, the D-mannitol derived chiral sulfide 42 serves as a useful chiral auxiliary in the sulfonium methylide epoxidation of aldehydes to provide terminal monosubstituted oxiranes (e.g., 44) in fair to excellent yield and good enantiomeric excess <04CC1076>. 

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