Alkenes from allylic halides

Cross-couplings. The enynes are formed from allyl halides and alkynylstannanes. The Ni(acac)2-catalyzed cross-coupling of alkyl iodides and diaUcylzincs is particularly useful because many functionalities are tolerated. An intramolecular addition to an alkene can intervene in this coupling thereby creating functionalized cyclic compounds. ... 

TT-Allyl palladium 939 complexes can be made directly from alkenes in a process that involves C-H activation (Scheme 9.11 - see Section 3.4), though they are more often made from allyl halides by treatment with a source of palladium(O) (Scheme 9.12). They are stable, isolable compounds, usually existing as dimers with... 

Conjugated dienes can be prepared by some of the methods previously discussed for preparing alkenes (Sections 11.7-11.10). The base-induced elimination of HX from an allylic halide is one such reaction. 

Monodehydrohalogenation of allylic halides is another classical method for diene synthesis24. This method is complementary to double dehydrohalogenation as both the 1,2-dihalides and allylic halides are readily accessed from alkenes. The commonly employed protocol for diene synthesis, particularly for cyclic 1,3-dienes, is through the allylic monobromination of the alkene with A-bromosuccinimide or related reagents followed by dehydrobromination with hindered bases such as DBN or DBU (equation l)25. 

This reaction involves the two reactants carbon monoxide and alcohol and produces esters, or lactones. The starting material, which will be considered here, is an alkene or an alkyne but it is also possible to start from activated halides (aryl- or allyl- iodides and bromides) to produce the same kind of organic products. 

The reaction starts with an oxidative addition of an allylic compound to palladium(O) and a Tt-allyl-palladium complex forms. Carboxylates, allyl halides, etc. can be used. In practice one often starts with divalent palladium sources, which require in situ reduction. This reduction can take place in several ways, it may involve the alkene, the nucleophile, or the phosphine ligand added. One can start from zerovalent palladium complexes, but very stable palladium(O) complexes may also require an incubation period. Good starting materials are the 7t-allyl-palladium intermediates ... 

Benzylic halides can be prepared by the same radical-halogenating agents that give allylic halides from alkenes. These include Cl2, Br2, N-bromo-succinimide (Section 14-3A), S02C12, and im-butyl hypochlorite (see Exercise 4-18) ... 

Allyltrimethylsilanes. Trimethylsilyllithium reacts with primary (E)-allylic halides to form the corresponding allyltrimethylsilanes. Reaction of the reagent prepared from (CH,),SiLi and Cul in HMPT with these halides results in the isomeric 3-trimethylsilyl-1-alkene. ... 

Cycloaddition reactions of 18-electron transition metal ti -allyl complexes with unsaturated electrophiles to form five-membered rings have been extensively investigated. These transformations constituted a family of metal-assisted cycloaddition reactions in which the metal functions as an electron-donor center. These are typically two-step processes that involve the initial formation of a dipolar metal r) -alkene intermediate (2) and subsequent internal cyclization (equation 2). The most extensively investigated application of this methodology has been with dicarbonyl-ii -cyclopentadienyliron (Fp) complexes from the laboratory of Rosenblum. These (ri -allyl)Fp complexes are available either by metallation of allyl halides or tosylates with a Fp anion, or by deprotonation of (alkene)Fp cations. ... 

In both cases we must consider the danger of enolate formation from the ketone. In the first case the alcohol might displace the bromide or attack the ketone and in the second the allylic bromide might be attacked at the alkene though this makes no difference as the allylic system is symmetrical. The first approach is easier as the bromoketone is easily made from acetone (Chapter 21) and the allylic halide in the second approach would probably be made from the alcohol used in the firs synthesis. 

Nickel(O) triphenylphosphine species have been used to convert allyl halides to 1,5-hexadiene [332], for the reductive coupling of ethylene with aryl halides to give 1,1-diaryl-ethanes [333], and for the coupling of aryl halides and alkenes to prepare substituted olefins [334], In addition, l,2-bis[(di-2-propylphosphino)benzene]nickel(0) has been used for the reductive coupling of aryl halides [335], and l,2-bis[(diphenylphosphino)ethane]-nickel(O) has been employed to synthesize biphenyl from bromobenzene [336] and to prepare benzoic acid from bromobenzene in the presence of carbon dioxide [337]. 

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