Wittig reaction phosphorus ylides

Keywords Wittig reaction, phosphorus ylide, ball-milling... 

This variation of the Wittig reaction uses ylides prepared from phosphonates.12 The Horner-Wadsworth-Emmons method has several advantages over the use of phosphoranes. These ylides are more reactive than the corresponding phosphoranes, especially when substituted with an electron withdrawing group. In addition the phosphorus product is a phosphate ester and soluble in water - unlike the Ph3PO product of the Wittig reaction - which makes it easy to separate from the olefin product. Phosphonates are also cheaper than phosphonium salts and can easily be prepared by the Arbuzov reaction from phosphanes and halides. 

In the Wittig reaction an aldehyde or ketone is treated with a phosphorus ylid (also spelled ylide and called a phosphorane) to give an alkene. The conversion of a carbonyl compound to an alkene with a phosphorus ylid is called the Wittig reaction. Phosphorus ylids are usually prepared by treatment of a phosphonium salt with a base, and phosphonium salts are usually prepared from a triaryl phosphine and an alkyl halide (10-31) ... 

The synthesis of vitamin Dj from a sensitive dienone was another etu-ly success of phosphorus ylide synthesis (H.H. Inhoffen, 1958 A). This Wittig reaction could be carried out without any isomerization of the diene. An excess of the ylide was needed presumably because the alkoxides formed from the hydroxy group in the educt removed some of the ylide. 

The phosphorus ylides of the Wittig reaction can be replaced by trimethylsilylmethyl-carbanions (Peterson reaction). These silylated carbanions add to carbonyl groups and can easily be eliminated with base to give olefins. The only by-products are volatile silanols. They are more easily removed than the phosphine oxides or phosphates of the more conventional Wittig or Homer reactions (D.J. Peterson, 1968). 

The Julia-Lythgoc olefination operates by addition of alkyl sulfone anions to carbonyl compounds and subsequent reductive deoxysulfonation (P. Kocienski, 1985). In comparison with the Wittig reaction, it has several advantages sulfones are often more readily available than phosphorus ylides, and it was often successful when the Wittig olefination failed. The elimination step yields exclusively or predominantly the more stable trans olefin stereoisomer. 

The Wittig reaction uses phosphorus ylides (called Wittig reagents) to convert aldehydes and ketones to alkenes... 

The Wittig reaction (Sections 17 12-17 13) Reaction of a phosphorus ylide with aldehydes and ketones leads to the formation of an alkene A versa tile method for the regiospecific prepa ration of alkenes... 

Wittig reaction (Section 17.12) Method for the synthesis of alkenes by the reaction of an aldehyde or a ketone with a phosphorus ylide. 

The reaction of an alkylidene phosphorane 1 (i.e. a phosphorus ylide) with an aldehyde or ketone 2 to yield an alkene 3 (i.e. an olefin) and a phosphine oxide 4, is called the Wittig reaction or Wittig olefination reaction. ... 

In the Wittig reaction, a phosphorus ylide, R2C—P(C6H03, also called a phosphoreme and sometimes written in the resonance form R2C=P(C6H5)3, adds to an aldehyde or ketone to yield a dipolar intermediate called a betaine. (An ylide—pronounced ill-id—is a neutral, dipolar compound with adjacent plus and minus charges. A betaine—pronounced bay-ta-een—is a neutral, dipolar compound with nonadjacent charges.)... 

Nucleophilic Addition of Phosphorus Ylides The Wittig Reaction 721... 

Active Figure 19.13 MECHANISM The mechanism of the Wittig reaction between a phosphorus ylide and an aldehyde or ketone to yield an alkene. Sign in at www.thomsonedu.com fo see a simulation based on this figure and to take a short Quiz. 

Wittig reaction (Section 19.11) The reaction of a phosphorus ylide with a ketone or aldehyde to yield an alkene. 

Retrosynthetic cleavage of the trans A8,9 disubstituted double bond in intermediate 11, the projected precursor of diketone 10, provides phosphorus ylide 12 and aldehyde 13 as potential precursors. In the forward sense, a Wittig reaction could conceivably achieve a convergent coupling of intermediates 12 and 13 with concomitant formation of the requisite trans C8-C9 olefin. Ordinarily, the union of a nonstabilized ylide, such as 12, with an aldehyde would be expected to afford an alkene with a cis geometry.8 Fortunately, however, the Schlosser modification of the Wittig reaction permits the construction of trans olefins from aldehydes and nonstabilized phosphorus ylides.9... 

In 2004, Whittlesey and Williams demonstrated that the reversible C-H activation of Ru-NHC complexes (e.g. 32a, Scheme 13.14) provides an effective manifold for tandem dehydrogenation/Wittig reaction/hydrogenation of alcohols, thus generating alkanes from alcohols and phosphorus ylides [56]. 

The stereoselectivity of the Wittig reaction is believed to be the result of steric effects that develop as the ylide and carbonyl compound approach one another. The three phenyl substituents on phosphorus impose large steric demands that govern the formation of the diastereomeric adducts.240 Reactions of unstabilized phosphoranes are believed to proceed through an early TS, and steric factors usually make these reactions selective for the d.v-alkcnc.241 Ultimately, however, the precise stereoselectivity is dependent on a number of variables, including reactant structure, the base used for ylide formation, the presence of other ions, solvent, and temperature.242... 

Some difficult Wittig reactions of stable phosphorus ylides with ketones have been accelerated by microwave irradiation (Scheme 6.17) [63]. When compared to conventional method, an improved yield has been achieved within a shorter time using MW irradiation in the absence of solvent. 

Organometallic betaines of type I can be considered as the closest structural analogs of carbon betaines of the (+ )P-C-C-X( ) type (IV), which were regarded for a long time as possible intermediates in classical reactions of carbonyl and thiocarbonyl compounds with phosphorus ylides (Wittig and Corey-Chaykovsky reactions and related processes,5,6 Scheme 1). Vedejs and coworkers7,8 proved unambiguously that oxapho-sphetanes (III) are true intermediates in the reactions of nonstabilized phosphorus ylides with carbonyl compounds. The formation of oxabetaines (+)p-c-c-o(-> was detected only in the form of their adducts with lithium salts.9,10... 

The spectral parameters of 15a and other silicon-organophosphorus betaines described henceforth in Section 2.2.2 allowed us to show reliably that the reaction of phosphorus ylides with thiocarbonyl compounds, unlike the classical Wittig reaction, occurs through the intermediate formation of betaines (17)11 (Scheme 9). Erker and coworkers performed a more detailed... 

As mentioned above (see Scheme 1), three main directions of the decomposition of intermediates that formed are possible when phosphorus and arsenic ylides react with compounds bearing C=X bonds 5,6,19,63,64,88 (i) elimination of R3E15=X to form olefins (Wittig type reaction) (ii) retro-Wittig type decomposition and (iii) elimination of R3E15 and formation of three-membered cycles (Corey-Chaykovsky type reaction). According to the data of Erker and coworkers,12,13,51 under kinetic control, the reaction of phosphorus ylides with thiocarbonyl compounds also affords phosphines and thiiranes, whose further transformations lead to olefins and R3PS under thermodynamic control. 

C5D5N above 80 °C, it gains the characteristic color of phosphorus ylide, and signals of phosphorus ylides and cyclosilathianes appear in the H, 13C, and 31P NMR spectra. In the presence of an equivalent amount of benzo-phenone in this solution, 1,1-dimethyl-2,2-diphenylethylene and Ph3PO are formed in 53% yield at 100 °C for 10min. This indicates that the retro-Wittig decomposition of 20a occurs in the solution (Scheme 23, equilibrium a). Probably, phosphorus ylide is also formed in the equilibrium bimolecular reaction between two betaine molecules (Scheme 23 equilibrium b). The ratio of the contributions of these two reactions is strongly determined by the solvent and temperature. 

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