Double bonds from elimination reactions

I Ignoring double-bond stereochemistry, what products would you expect from elimination reactions of the following alkyl halides Which will be the major product in each case ... 

Reactions leading to the formation of the catalytically active nickel hydride species from organonickel precursors (Section III) can be regarded as model reactions for olefin oligomerization reactions. The reactions described by Eq. (8) and Scheme 3 (Section III) show that RNiX compounds (R = methyl orallyl, X = halide or acetylacetonate) activated by Lewis acids add to double bonds under mild reaction conditions (-40° or 0°C). It follows further from these reactions that under conditions leading to olefin dimerization a rapid nickel hydride /3-hydrogen elimination reaction occurs. The fact that products resulting from olefin insertion into the nickel-carbon bond are only observed when /3-hydride... 

Addition of hydrosilane to alkenes, dienes and alkynes is called hydrosilylation, or hydrosilation, and is a commercially important process for the production of many organosilicon compounds. As related reactions, silylformylation of alkynes is treated in Section 7.1.2, and the reduction of carbonyl compounds to alcohols by hydrosilylation is treated in Section 10.2. Compared with other hydrometallations discussed so far, hydrosilylation is sluggish and proceeds satisfactorily only in the presence of catalysts [214], Chloroplatinic acid is the most active catalyst and the hydrosilylation of alkenes catalysed by E PtCU is operated commercially [215]. Colloidal Pt is said to be an active catalytic species. Even the internal alkenes 558 can be hydrosilylated in the presence of a Pt catalyst with concomitant isomerization of the double bond from an internal to a terminal position to give terminal silylalkanes 559. The oxidative addition of hydrosilane to form R Si—Pt—H 560 is the first step of the hydrosilylation, and insertion of alkenes to the Pt—H bond gives 561, and the alkylsilane 562 is obtained by reductive elimination. 

Transmetallation of silyl enol ethers of ketones and aldehydes with Pd(II) generates Pd(II) enolates, which are usefull intermediates. Pd(II) enolates undergo alkene insertion and -elimination. The silyl enol ether of 5-hexen-2-one (241) was converted to the Pd enolate 242 by transmetallation with Pd(OAc)2, and 3-methyl-2-cyclopentenone (243) was obtained by intramolecular insertion of the double bond and -elimination [148], Formally this reaction can be regarded as carbopalladation of alkene with carbanion. Preparation of the stemodin intermediate 246 by the reaction of the silyl enol ether 245, obtained from 244, is one of the many applications [149]. Transmetallation and alkene insertion of the silyl enol ether 249, obtained from cyclopentadiene monoxide (247) via 248, afforded 250, which was converted to the prostaglandin intermediate 251 by further alkene insertion. In this case syn elimination from 250 is not possible [150]. However, there is a report that the reaction proceeds by oxypalladation of alkene, rather than transmetallation of silyl enol ether with Pd(OAc)2 [151]. 

This reaction type is called the ElcB mechanism, which stands for unimolecular elimination conjugate base reaction, because the conjugate base of the starting material is being formed as the reactive intermediate. It is sometimes called the carbanion mechanism. As this mechanism results from the removal of a proton, it is not surprising that it is favoured by those substrates that possess an acidic hydrogen atom. Thus, would you expect the ElcB mechanism to be more prevalent in reactions that result in a carbon/carbon double bond or in reactions that result in a carbon/carbon triple bond ... 

The double elimination of 1,1-dichlorocyclopropanes with potassium tert-butoxide to give cycloproparenes is an important variant of the reaction discussed in Section 5.2.2.1.2.3. When a six-membered ring fused to the cyclopropane contains a double bond, the elimination is accompanied by isomerization of the new double bonds to give an aromatic ring (Table 7). The reaction is illustrated by the synthesis of bicyclo[4.1.0]hepta-l,3,5-triene (l//-cyclo-propabenzene, 3) in two steps from cyclohexa-1,4-diene (1), the first step being dichlorocarbene addition to the diene to give 7,7-dichlorobicyclo[4.1.0]hept-3-ene... 

Alkenes and alkynes are prepared by elimination reactions in which a carbon-carbon single bond is converted to a double or triple bond. In elimination reactions, atoms or groups are eliminated from adjacent carbons. Elimination once produces double bonds twice produces triple bonds. 

More general routes to rings containing one double bond utilize elimination of an alcohol from a 2-alkoxy derivative of the saturated ring system or elimination of water, which frequently occurs under cyclization conditions. Thus, acid-catalyzed reactions of a-hydroxy ketones with ethylene glycol, 2-thiolethanol, and 1,2-ethanedithiol furnish, in most cases, the corresponding dihydro-... 

The facile dechlorination of the comer chlorines of the pesticide Mirex, 2, is of particular interest. These chlorines cannot be removed by nucleophilic substitution because nucleophiles cannot get inside the cage to approach carbon from the backside in Sn2 reactions. Elimination reactions are also in ossible since double bonds from these comer carbons can t be formed due to the constrained geometry. However, solvated electron solutions readily and conq>letely dechlorinate Mirex. ... 

Notwithstanding the enormous diversity of free-radical processes, the following most common elementary reactions may be singled out 1) cleavage of the atom X, usually a hydrogen atom, by a radical from the R—X bonds 2) addition of the radical to the double bond and 3) reactions of radical (homolytic) substitution Sh2 proceeding without intermediates. Some other processes, for example, the widespread reactions of radical aromatic substitution and the type of Eq. (8.1) reactions occur as a combination of two elementary steps by the addition-elimination mechanism (AdE). 

The Peterson olefination concerns the construction of double bonds from trialkylsilyl-substituted organometallics and carbonyls. The reaction involves the formation of an /ar-hydroxysilane, which then undergoes elimination to give the alkene. Elimination can take place under either acidic or basic conditions. 

D-arabo-i-nitrohexene-i, by using the Schmidt and Rutz reaction for the preparation of nitro lefines from nitro-alcohols. Starting with this compound O Neill prepared iV-acetyl-D-mannosamine by addition of NH3 to the double bond and elimination of the nitro group by means of the Nef reaction. ... 

Barrelene was obtained via a double Diels-Alder reaction from a-pyrone with methyl acrylate (H.E. Zimmerman, I969A). The primarily forming bicyclic lactone decarboxylates in the heat, and the resulting cyclohexadiene rapidly undergoes another Diels-Alder cyclization. Standard reactions have then been used to eliminate the methoxycarbonyl groups and to introduce C—C double bonds. Irradiation of barrelene produces semibullvalene and cyclooctatetraene (H.E. Zimmerman. 1969B). 

The reaction of allyl halides with terminal alkynes by use of PdClifFhCNji as a catalyst affords the l-halo-l,4-pentadienes 297. 7r-AlIylpalladium is not an intermediate in this reaction. The reaction proceeds by chloropalladation of the triple bond by PdCh, followed by the insertion of the double bond of the allyl halide to generate 296. The last step is the regeneration by elimination of PdCh, which recycles[148]. The cis addition of allyl chloride to alkynes is supported by formation of the cyclopentenone 299 from the addition product 298 by Ni(CO)4-catalyzed carbonylation[149]. 

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