Alkyl groups dehydrohalogenation

If there is possibility of formation of more than one alkene due to the availability of more than one 3-hydrogen atoms, usually one alkene is formed as the major produet. These form part of a pattern first observed by Russian ehemlst, Alexander Zaitsev (also pronounced as Saytzeff) who In 1875 formulated a rule which can be summarised as in dehydrohalogenation reactions, the preferred product is that alkene which has the greater number of alkyl groups attached to the doubly bonded carbon atoms. Thus, 2-bromopentane gives pent-2-ene as the major product. 

Similarly, the 2-cyano-6-oxazolopiperidine 75 (Scheme 16) can be used to provide a variety of substituted piperidines <99TL3731, 99H(51)2065>. Conversion to the enamide 76 provides a means to introduce C-3 alkyl groups by Michael reaction <99TL3699>. Electrochemical bis-bromination and dehydrohalogenation affords the vinyl bromide 77, which can imdergo substitution at the 4-position by the addition of nucleophiles as simple as water <99T8931>. 

In small amounts it catalyses the formation of terminal alkenes, e.g. from alkyl bromides or iodides in the presence of BuLi/DBU in THE at 25° in 50-80% yields [Jerapoulos Smith JCN Chem Commun 16211986], It also catalyses the replacement of OH groups in allyl acohols with the alkyl group of alkylmagnesimn bromide thus forming a C-C bond, and also causes dehydrohalogenation of alkylhalides to form the corresponding terminal olefin [Chuit et al. JCS Chem Commun 1604 1986],... 

Geometrical Considerations in the E2 Elimination Reaction. Base-induced elimination of alkyl halides (dehydrohalogenation) is a general reaction and is an excellent method for preparing alkenes.This process is often referred to as -elimination, since a hydrogen atom is always removed p to the halide (leaving group) ... 

Two aspects of dehydrohalogenation, both based on the stabilization of double bonds by alkyl groups, are accommodated by the E2 mechanism. As shown earlier (Section 5.14), the reaction ... 

This concludes discussion of our second functional group transformation mvolv mg alcohols the first was the conversion of alcohols to alkyl halides (Chapter 4) and the second the conversion of alcohols to alkenes In the remaining sections of the chap ter the conversion of alkyl halides to alkenes by dehydrohalogenation is described... 

We have previously seen (Scheme 2.9, enby 6), that the dehydrohalogenation of alkyl halides is a stereospecific reaction involving an anti orientation of the proton and the halide leaving group in the transition state. The elimination reaction is also moderately stereoselective (Scheme 2.10, enby 1) in the sense that the more stable of the two alkene isomers is formed preferentially. Both isomers are formed by anti elimination processes, but these processes involve stereochemically distinct hydrogens. Base-catalyzed elimination of 2-iodobutane affords three times as much -2-butene as Z-2-butene. 

Cyclohexyl bromide, for exfflnple, is converted to cyclohexene by sodium ethoxide in ethanol over 60 times faster than cyclohexyl chloride. Iodide is the best leaving group in a dehydrohalogenation reaction, fluoride the poorest. Fluoride is such a poor leaving group that alkyl fluorides are rarely used as starting materials in the preparation of alkenes. 

Alkynes are prepared from alkyl dihalides via elimination of atoms or groups from adjacent carbons. Dehydrohalogenation of vicinal- or gemiwaZ-dihahdes is a particularly useful method for the preparation of alkynes (see Section 5.4.5). 

In 1,2-elimination, e.g. dehydrohalogenation of alkyl halide, the atoms are removed from adjacent carbons. This is also called -elimination, because a proton is removed from a P-carbon. The carbon to which the functional group is attached is called the a-carbon. A carbon adjacent to the a-carbon... 

C(R)=NR group with a nitrilium salt RCssNR .222 The acylation of the enamine can take place by the same mechanism as alkylation, but another mechanism is also possible, if the acyl halide has an a hydrogen and if a tertiary amine is present, as it often is (it is added to neutralize the HX given off). In this mechanism, the acyl halide is dehydrohalogenated by the tertiary amine, producing a ketene (7-14) which adds to the enamine to give a cyclobutanone (5-49). This compound can be cleaved in the solution to form the same acylated imine salt (27) that would form by the more direct mechanism, or it can be isolated (in the case of enamines derived from aldehydes), or it may cleave in other ways.223... 

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