Alkenes followed by elimination

Trifluoromethyl-substituted pyrazoles are easily obtained using trifluoromethyl-alkynes as dipolarophiles (Table 8.2, entry 9). Thus, treatment of 4,4,4-trifluorobut-2-ynoic acid with excess diazomethane gave methyl 4-(trifluoromethyl)pyrazole-4-carboxylate (45%) accompanied by its N - (32%) and -methylated (6.5%) derivatives (267). Another convenient route to CF3-substituted pyrazoles involves dipolar cycloaddition of appropriately CF3-substituted alkenes followed by eliminative aromatization (76,77,268). For example, the reaction of alkenes such as (CF3)2C=C(H)COAr with ethyl diazoacetate gave 4-aroyl-5-trifluoromethylpyra-zole-3-carboxylates (268). 

Oxytelluration of terminal alkenes followed by elimination of the tellurium moiety gives enol ethers as shown in Scheme 7. ... 

A carbonyl is reduced to an alcohol (Chapter 19) and an alcohol is oxidized to a carbonyl (Chapter 17). The OH unit of an alcohol is converted to an X group, where X is a halide (or a sulfonate ester), by standard means (Chapter 11, Section 11.7) and hydrolysis of a halide or a sulfonate ester gives an alcohol (Chapter 11, Section 11.4). Elimination of a halide leads to an alkene (Chapter 12, Section 12.1) and addition of HX to an alkene gives C-Xmolecrdes (Chapter 10). Addition of two equivalents of a halogen to an alkene, followed by elimination, leads to an alkyne (Chapter 12) reduction of the alkyne gives the alkene again (Chapter 19). 

The construction of the cyclobutane of 1 was effected by an interesting application of the Negishi reagent (Cp ZtCyi x BuLi). Complexation of Cp Zr with the alkene followed by elimination generated an allylic organometallic 11, which added to the released aldehyde to give the cyclobutanes 12 and 13 in a 2.4 1 diastereomeric ratio. 

As a further application of the reaction, the conversion of an endocyclic double bond to an c.xo-methylene is possible[382]. The epoxidation of an cWo-alkene followed by diethylaluminum amide-mediated isomerization affords the allylic alcohol 583 with an exo double bond[383]. The hydroxy group is eliminated selectively by Pd-catalyzed hydrogenolysis after converting it into allylic formate, yielding the c.ro-methylene compound 584. The conversion of carvone (585) into l,3-disiloxy-4-methylenecyclohexane (586) is an example[382]. 

Chemical Properties. Reactions of quaternaries can be categorized iato three types (169) Hoffman eliminations, displacements, and rearrangements. Thermal decomposition of a quaternary ammonium hydroxide to an alkene, tertiary amine, and water is known as the Hoffman elimination (eq. la) (170). This reaction has not been used extensively to prepare olefins. Some cycHc olefins, however, are best prepared this way (171). Exhaustive methylation, followed by elimination, is known as the Hoffman degradation and is important ia the stmctural determination of unknown amines, especially for alkaloids (qv) (172). 

The Julia olefination involves the addition of a sulfonyl-stabilized carbanion to a carbonyl compound, followed by elimination to form an alkene.277 In the initial versions of the reaction, the elimination was done under reductive conditions. More recently, a modified version that avoids this step was developed. The former version is sometimes referred to as the Julia-Lythgoe olefination, whereas the latter is called the Julia-Kocienski olefination. In the reductive variant, the adduct is usually acylated and then treated with a reducing agent, such as sodium amalgam or samarium diiodide.278... 

Dimethylsulfonium methylide reacts with reactive alkylating reagents such as allylic and benzylic bromides to give terminal alkenes. A similar reaction occurs with primary alkyl bromides in the presence of Lil. The reaction probably involves alkylation of the ylide, followed by elimination.289... 

SCHEME 7.16 Reductive alkylation of the alternating DNA polymer, poly d(GC), at the guanine N(7) position followed by elimination to afford the alkene. 

The regioselective addition of nitryl iodide to alkenes, followed by base-induced elimination, gives nitroalkenes. Nitryl iodide is generally prepared by the reaction of AgN02 and iodine. 

Crozet and co-workers have used S l reactions for synthesis of new heterocycles, which are expected to be biologically active (see also Section 7.3, which discusses synthesis of alkenes). For example, 2-chloromethyl-5-nitroimidazole reacts with the anion of 2-nitropropane to give 2-isopropylidene-5-nitroimidazole. It is formed via C-alkylation of the nitronate ion followed by elimination of HN02 (Eq. 5.33).51a Other derivatives of nitroimidazoles are also good substrates for SrnI reactions.5113 0... 

Dipolar cycloaddition reaction of azomethine ylides to alkynes or alkenes followed by oxidation is one of the standard methods for the preparation of pyrroles.54 Recently, this strategy has been used for the preparation of pyrroles with CF3 or Me3Si groups at the (3-positions.55 Addition of azomethine ylides to nitroalkenes followed by elimination of HN02 with base gives pyrroles in 96% yield (Eq. 10.48).56... 

Chloro-l-alkenesS A regioselective route to these chloroalkenes involves thermodynamically controlled addition of C6H5SeCl to a 1-alkene followed by chlorination to provide a (2-chloroalkyl)phenylselenium dichloride (2). These products undergo elimination when treated with NaHC03 in a two-phase system to provide 2-chloro-l-alkenes (3). 

Disubstituted alkynes and terminal alkynes form E-dibromoalkenes [4] when the tribromide is formed in situ in an essentially basic medium, an addition reaction followed by elimination of hydrogen bromide results in the conversion of terminal alkynes into the 1-bromoalkynes [5]. When the addition reaction is conducted in methanol, l,l-dibromo-2,2-dimethoxyalkanes are produced, in addition to the 1,2-dibromoalkenes [6], The dimethoxy compounds probably result from the initial intermediate formation of bromomethoxyalkenes. Under similar conditions, alkenes yield methoxy bromo compounds [7]. 

From Chapter 7 it is apparent that the trichloromethyl anion is formed under basic conditions from chloroform, as a precursor of the carbene. The anion can also react with Jt-deficient alkenes (see Section 7.3) and participate in nucleophilic substitution reactions, e.g. 1,1-diacyloxy compounds are converted into 1,1,1-trichloroalkan-2-ols [58] (Scheme 6.35). Similarly, benzyl bromides are converted into (2-bromoethynyl)arenes via an initial nucleophilic displacement followed by elimination of hydrogen bromide [59] (Scheme 6.35). 

The first steps involve coordination and cycloaddition to the metal. Insertion of a third molecule of ethene leads to a more instable intermediate, a seven-membered ring, that eliminates the product, 1-hexene. This last reaction can be a (3-hydrogen elimination giving chromium hydride and alkene, followed by a reductive elimination. Alternatively, one alkyl anion can abstract a (3-hydrogen from the other alkyl-chromium bond, giving 1-hexene in one step. We prefer the latter pathway as this offers no possibilities to initiate a classic chain growth mechanism, as was also proposed for titanium [8]. The byproduct observed is a mixture of decenes ( ) and not octenes. The latter would be expected if one more molecule of ethene would insert into the metallocycloheptane intermediate. Decene is formed via insertion of the product hexene into the metallo-cyclopentane intermediate followed by elimination. 

Catalysis of hydrosilylation by dimeric or by monomeric rhodium (and iridium) siloxide complexes occurs via preliminary oxidative addition of siUcon hydride followed by elimination of disiloxane (detected by GC/MS) to generate the square planar 16e hydride complex with an already coordinated molecule of alkene (Scheme 7.7). 

Af-(Silylmethyl)thioimidates (34) also undergo water-induced desilylation leading to the N-protonated azomethine ylides (38). These ylides react with a range of electron-deficient alkenes and alkynes, aldehydes, and ketones followed by elimination of methane thiol to give formal nitrile ylide adducts (e.g., 40) (23,24). The reactivity of these species is rather dependent on the nature of R (e.g., good for R = Ph but less so for R=Et or i-Pr), which may be due to competition from tautomerization to give the A -methylthioimidate (39). 

During slow thermal chlorination, elimination of HC1 from the monochloride with the resultant formation of an alkene followed by chlorine addition may be the dominant route to yield dichloroalkanes. This mechanism, however, is negligible in rapid thermal or photochemical reactions. 

Replacement of fluorine occurs when l,l,l-trifluoro-2,2-dihaloethanes 1 are treated with alkaline alkoxides.59 The products, alkyl 1,1 -difluoro-2,2-dihaloethyl ethers, are probably formed by two separate reactions these are elimination of hydrogen fluoride to give an alkene, followed by addition of the alcohol.59... 

In the absence of base, vinylmercury reagents and lithium tetrachloropalladate(II) react with alkenes to form ir-allylpalladium complexes arising from addition of the vinylpalladium chloride to the alkene followed by palladium hydride elimination, a reverse readdition and rr-allyl formation (equation 10).31... 

Sometimes, an alkene conjugated with a ketone is introduced during a Swern oxidation.172a 232 This can be explained by an a-chlorination followed by elimination of HC1. 

Both of die latter two methods of elimination are part of a longer sequence of reactions tiiat produce olefins. Initial formation of a single bond to a carbonyl carbon is followed by elimination to an alkene. Thus die alkene is a condensation product of two smaller units. Schematically,... 

The Heck reaction involves the coupling of an organopalladium species formed by oxidative addition to an alkene followed by /S-hydride elimination. The product is an alkene in which a vinyl hydrogen on the original alkene is replaced by die organic group on palladium. Thus aryl and alkenyl halides can be coupled to alkenes. 

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