Reactions olefination

Hanessian resolved alkylqrclohexanones by benzylidenation with a chiral olefination reagent arising from R,R)-103 [71]. Treatment of ( )-2-methylcyclohexanone 104 with 0.5 Molar equiv of the anion of 103 gave ( ,2S)-(2-methylcyclohexane)-benzylidene 105 (together with 2% of the Z-isomer), in 34% yield, based on the ketone (63% based on the chiral reagent). Analogously, ( )-cts-2,4-dimethylcyclohexanone 106 afforded the 3-hydroxyphosphonamide 107, then the ( ,2R,4i )-(2,4-dimethylcyclohexane)-benzylidene 108 in 30% yield and over 99% ee. 

Rein et ul. [72] studied KR of the dimer of acrolein 109 with chiral phospho-nate reagents, with different types of substituents on phosphorus. The use of 

Reaction of the chiral phosphonopropionate 112 with the aldehyde 111 afforded almost exclusively the (R,Z)-diastereomer [70]. The ( )-product was not detected. Although the mechanism and stereochemical course of the reaction is not fully elucidated, it seems likely that the initial step is irreversible under the reaction conditions and hence the (Z)/( ) ratio and the diastereomer ratios result from kinetic control in the initial step. Olefination reagent 112 therefore displays a high enantiomer selectivity for aldehyde 111 [73]. 

The same type of olefination reaction has been carried out with N-diphenylphosphinoyl aldehyde 113 with chiral phosphonates of type 114 [74], The authors were interested in selective generation of the products and showed that a proper choice of reaction parameters (R group of the phosphonate, base and solvent) enabled the production of any one of the four possible stereoisomers as the major product 

In olefination reactions of racemic 2-alkylsubstituted cyclohexanones with the chiral phosphonoacetate 115 obtained from natural D-mannitol, the unreacted ketone could be recovered in enantiomerically enriched form, provided the base was not in too high a concentration [75]. 

---

Oxidative Carbonylation of Ethylene—Elimination of Alcohol from p-Alkoxypropionates. Spectacular progress in the 1970s led to the rapid development of organotransition-metal chemistry, particularly to catalyze olefin reactions (93,94). A number of patents have been issued (28,95—97) for the oxidative carbonylation of ethylene to provide acryUc acid and esters. The procedure is based on the palladium catalyzed carbonylation of ethylene in the Hquid phase at temperatures of 50—200°C. Esters are formed when alcohols are included. Anhydrous conditions are desirable to minimize the formation of by-products including acetaldehyde and carbon dioxide (see Acetaldehyde). 

Acetylene and hydrogen chloride historically were used to make chloroprene [126-99-8]. The olefin reaction is used to make ethyl chloride from ethylene and to make 1,1-dichloroethane from vinyl chloride. 1,1-Dichloroethane is an intermediate to produce 1,1,1-trichloroethane by thermal (26) or photochemical chlorination (27) routes. 

Commercial Olefin Reactions. Some of the more common transformations involving a-olefins ia iadustrial processes iaclude the oxo reaction (hydroformylation), oligomerization and polymerization, alkylation reactions, hydrobromination, sulfation and sulfonation, and oxidation. 

Sulfation and Sulfonation. a-Olefin reactions involving the introduction of sulfur-containing functional groups have commercial importance. As with many derivatives of olefins, several of these products have appHcations in the area of surfactants (qv) and detergents. Typical sulfur reagents utilized in these processes include sulfuric acid, oleum, chlorosulfonic acid, sulfur trioxide, and sodium bisulfite. 

In keeping with its aromatic character, pyrrole is relatively difficult to hydrogenate, it does not ordinarily serve as a diene for Diels-Alder reactions, and does not undergo typical olefin reactions. Klectrophilic substitutions are the most characteristic reactions, and pyrrole has often been compared to phenol or... 

Base catalysis is most effective with alkali metals dispersed on solid supports or, in the homogeneous form, as aldoxides, amides, and so on. Small amounts of promoters form organoalkali comnpounds that really contribute the catalytic power. Basic ion exchange resins also are usebil. Base-catalyzed processes include isomerization and oligomerization of olefins, reactions of olefins with aromatics, and hydrogenation of polynuclear aromatics. 

Contents Introduction and Principles. - The Reaction of Dichlorocarbene With Olefins. - Reactions of Dichlorocarbene With Non-Olefinic Substrates. -Dibromocarbene and Other Carbenes. - Synthesis of Ethers. - Synthesis of Esters. - Reactions of Cyanide Ion. - Reactions of Superoxide Ions. - Reactions of Other Nucleophiles. - Alkylation Reactions. - Oxidation Reactions. - Reduction Techniques. - Preparation and Reactions of Sulfur Containing Substrates. -Ylids. - Altered Reactivity. - Addendum Recent Developments in Phase Transfer Catalysis. 

The most common method of epoxidation is the reaction of olefins with per-acids. For over twenty years, perbenzoic acid and monoperphthalic acid have been the most frequently used reagents. Recently, m-chloroperbenzoic acid has proved to be an equally efficient reagent which is commercially available (Aldrich Chemicals). The general electrophilic addition mechanism of the peracid-olefin reaction is currently believed to involve either an intra-molecularly bonded spiro species (1) or a 1,3-dipolar adduct of a carbonyl oxide, cf. (2). The electrophilic addition reaction is sensitive to steric effects. 

Fluoroalkylphosphonates may also be deprotonated for use in olefination reactions with aldehydes [77] (equation 64)... 

Table 25. Olefination Reactions with Diethyl Phosphonofluoro-acetonitrile (EtO)jP(0)CHFCN...

FYedictably, fluoroketones undergo olefination reactions with more reactive arsonium ylides [35] (equation 28). 

Fluonnated aldehydes, where the fluorine is located a to the carbonyl [40] or more remotely, undergo olefination reactions cleanly [41, 42, 43] (equation 32) (Table 11)... 

Table 11. a-and (3-Fluorinated a, 3-Unsaturated Aldehydes in Olefination Reactions [43 ... 

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. ... 

Olefin Reaction time for addition (minutes) Product bp of product (1 atm) (X)... 

Olefins, reaction with nitrones, 46,130 cjs-Olefins f lom disubstituted acetylenes by selective reduction v ith modi fied palladium (Lindlar) catalyst, 46,92... 

Since electron-donating substituents at the phosphorus atom favor addition reactions over olefination reactions, addition of 9 to aldehydes leads to the exclusive formation of the silyl-pro-tected allylic alcohols 10. No reaction products arising from Wittig alkenylation could be detected. The ylides (R,S)-9 and (S.S)-9 and their enantiomers were prepared from the corresponding optically pure l-[2-(diphenylphosphino)ferrocenyl]-A,A -dimethylethanamine diastereomers 7 via the phosphonium salts 8. 

Alkyl mercuric hydrides are generated in situ by reduction of an alkyl mercuric salt with sodium borohydridc (Scheme 3.91). Their use as radical traps was first reported by Hill and Whitesides491 and developed for the study of radical-olefin reactions by Giese,489490 Tirrell492 and coworkers. Careful choice of reagents and conditions provides excellent yields of adducts of nucleophilic radicals (e.g. -hexyl, cyclohexyl, /-butyl, alkoxyalkyl) to electron-deficient monomers (e.g. acrylics). 

M is an unsaturated hydrocarbon or an organic compound such as CH3OH, CH3I, CH3N02, (CH3)2CO, CH3NH2, etc. When M is an olefin, Reaction 27 or 28 will compete with a hydride transfer process (see earlier discussion) and a condensation process. For instance, in the radiolysis of C3D8-CH3CHCH2 mixtures (9), the relative rates of Reactions 29, 30, 31, and 32... 

These reactions proceed without solvent as well (Reaction 29)7 On the other hand, reaction in the presence of AICI3 in CH2CI2 gave exclusively gem-disubstituted olefins (Reaction 30)7 The presence of Lewis acid shifts the reaction mechanism from radical to ionic, affording a complementary regios-electivity. 

The reactivity of a remarkable electronically unsaturated tantalum methyli-dene complex, [p-MeCgH4C(NSiMe3)2]2Ta( = CH2)CH3, has been investigated. Electrophilic addition and olefination reactions of the Ta = CH2 functionality were reported. The alkylidene complex participates in group-transfer reactions not observed in sterically similar but electronically saturated analogs. Reactions with substrates containing unsaturated C-X (X = C, N, O) bonds yield [Ta] = X compounds and vinylated organic products. Scheme 117 shows the reaction with pyridine N-oxide, which leads to formation of a tantalum 0x0 complex. ... 

For all the olefins studied, alkyl-, fluoro-, or chloro-substituted, three binary, mononuclear species were observed. It now seems that it is a general property of Ni and Pd atom-olefin reactions at cryogenic temperatures to form complexes that have a maximum coordination of three olefin molecules per metal atom, regardless of the electronic or steric attributes of the substituent(s). As intimated previously, the absence of higher stoichiometry species, even for unsubstituted ethylene, is, most probably, the result of steric interactions (54). 

Evans Jr. and coworkers reported a similar olefination reaction employing spirooxyphosphoranes of type 66. Upon treatment with a strong base (LiHMDS) and subsequent addition of benzaldehyde, the reaction proceeded to form anionic P(VI) intermediates (67,6 -106 to -116 ppm) that decomposed at room temperature to form the corresponding olefins and spiropentaoxyphosphoranes [ 105]. The stereoselectivity (E Z ratio) of the double bond-forming reaction depended upon the conditions evidence indicated the possibility of kinetic or thermodynamic control (Scheme 21). 

The main aim of this review is to survey the reactions by which the Co—C bond is made, broken, or modified,.and which may be used for preparative purposes or be involved in catalytic reactions. Sufficient evidence is now available to show that there exists a general pattern of reactions by which the Co—C bond can be made or broken and in which the transition state may correspond to Co(III) and a carbanion (R ), Co(II) and a radical (R-), Co(I) and a carbonium ion (R ), or a cobalt hydride (Co—H) and an olefin. Reactions are also known in which the organo ligand (R) may be reversibly or irreversibly modified (to R ) without cleavage of the Co—C bond, or in which insertion occurs into the Co—C bond (to give Co—X—R). These reactions can be shown schematically as follows ... 

A more practical catalytic system is based on the use of air-stable [Fe(TTP)Cl] as catalyst, which can efficiently catalyze the olefination reactions at 80°C in excellent yields and high trans-selectivity [71] (Scheme 18). 

Olefination Reactions Involving Phosphonium Ylides. The synthetic potential of phosphonium ylides was developed initially by G. Wittig and his associates at the University of Heidelberg. The reaction of a phosphonium ylide with an aldehyde or ketone introduces a carbon-carbon double bond in place of the carbonyl bond. The mechanism originally proposed involves an addition of the nucleophilic ylide carbon to the carbonyl group to form a dipolar intermediate (a betaine), followed by elimination of a phosphine oxide. The elimination is presumed to occur after formation of a four-membered oxaphosphetane intermediate. An alternative mechanism proposes direct formation of the oxaphosphetane by a cycloaddition reaction.236 There have been several computational studies that find the oxaphosphetane structure to be an intermediate.237 Oxaphosphetane intermediates have been observed by NMR studies at low temperature.238 Betaine intermediates have been observed only under special conditions that retard the cyclization and elimination steps.239... 

Olefination Reactions Involving Phosphonate Anions. An important complement to the Wittig reaction involves the reaction of phosphonate carbanions with carbonyl compounds 253 The alkylphosphonic acid esters are made by the reaction of an alkyl halide, preferably primary, with a phosphite ester. Phosphonate carbanions are generated by treating alkylphosphonate esters with a base such as sodium hydride, n-butyllithium, or sodium ethoxide. Alumina coated with KF or KOH has also found use as the base.254... 

Scheme 2.18 gives some representative olefination reactions of phosphonate anions. Entry 1 represents a typical preparative procedure. Entry 2 involves formation of a 2,4-dienoate ester using an a, 3-unsaturated aldehyde. Diethyl benzylphosphonate can be used in the Wadsworth-Emmons reaction, as illustrated by Entry 3. Entries 4 to 6 show other anion-stabilizing groups. Intramolecular reactions can be used to prepare cycloalkenes.264... 

---