Alkyl elimination reactions

An unusual one-pot intramolecular sulfoxide alkylation-elimination reaction was found by Gibson et al. <2001SL712>. These authors found that treatment of 459 with potassium bis-trimethylsilylamide resulted in a ring closure to 460 in acceptable yield. Furthermore, Batori and Messmer found an effective method for preparation of [l,2,3]triazolo[l,5- ]pyrimidinium salts <1994JHC1041> oxidative cyclization of hydrazones 461 by 2,4,4,6-tetrabromo-2,5-cyclohexadienone gave rise to the quaternary salts 462. Under certain reaction conditions, the formation of 6-bromo-salts 462 (R6 = Br) was also experienced. As neither the starting compound nor the quaternary triazolopyridinium salt underwent bromination in this position, the authors assumed that this bromination process occurred on one of the intermediates in the course of the above-mentioned cyclization reaction. 

Although the amount of cracking was generally low, some comments can be asserted about the reactions taking place. The detection of diphenyl may indicate some cracking of H2P initially to form ethyldiphenyl or dimethyldiptenyl followed by alkyl elimination reactions. 

Except for a 1960 report on one alkylaluminum system 104), no /3-alkyl elimination reactions of this type had ever been observed. Thus, this reaction provided another example in which lanthanide systems demonstrated special organometallic chemistry. 

The problem here is to decide between the elimination-addition and substitution mechanisms of alkylations. Elimination reactions were therefore studied first. 2-Piperidinomethylcyclopentanone (4) and -piperidinopropiophenone (6) were the first Mannich bases examined (Horak et al., 1961). Reactions (2a) and (2b) were expected. Equation (3) is a general formulation. 

Other activated sulfoxides. This alkylative elimination reaction has been extended by Trost and Bridges to a one-pot synthesis of alkenes, vinyl sulfides, a, l-unsaturated sulfoxides, and a,j3-unsaturated nitriles. The sulfoxides (1-4) are converted into the anions by lithium N-isopropylcyclohexylamide or sodium hydride and are then alkylated at 20° in THE or DME elimination is then effected by raising the temperature to reflux. In some cases trimethyl phosphite is added as a scavenger for phenylsulfenic acid. Typical results are formulated in the equations. The elimination reaction is facilitated by an aryl, thioaryl, or... 

Single-electron oxidation of the Ru(II) complexes TpRu(R)(L)(L ) (L = CO, L = NCMe, R = Me, CH2CH2Ph L = L = PMe3, R = Me) with AgOTf leads to alkyl elimination reactions that produce TpRu(OTf)(L)(L ) and organic products that likely result from Ru-Caikyi bond homolysis.This reaction apparently proceeds via a Ru(III) species. Calculations have shown that homolytic Ru-C bond cleavage is far more facile if the metal center is in the + III oxidation state. 

The /3-alkyl elimination reaction (47) suggests that such a process may be the chain-terminating step in the [Lu(7/ -C5Me5)2Me]-catalyzed oligomerization of propene/ ... 

N,N,N, N -tetramethyl-l,8,-naph-thalenediamiDe M.P. 51 C. A remarkably strong mono-acidic base (pKg 12-3) which is almost completely non-nucleophilic and valuable for promoting organic elimination reactions (e.g. of alkyl halides to alkenes) without substitution. 

It has been tentatively suggested that one mechanism underlies the Willgerodt reaction and the Kindler modification of it. A labile intermediate is first formed which has a carbon—carbon bond in the side chain. The scheme is indicated below it postulates a series of steps involving the addition of ammonia or amine (R = H or alkyl), elimination of water, re addition and eUmination of ammonia or amine until the unsaturation appears at the end of the chain then an irreversible oxidation between sulphur and the nitrogen compound may occur to produce a thioamide. 

Preparation of Alkenes by Elimination Reactions of Alcohols and Alkyl Halides... 

When we discussed elimination reactions in Chapter 5 we learned that a Lewis base can react with an alkyl halide to form an alkene In the present chapter you will find that the same kinds of reactants can also undergo a different reaction one m which the Lewis base acts as a nucleophile to substitute for the halo gen substituent on carbon... 

Nucleophilic substitution reactions of alkyl halides are related to elimination reactions m that the halogen acts as a leaving group on carbon and is lost as an anion The... 

We have seen that an alkyl halide and a Lewis base can react together m either a sub stitution or an elimination reaction... 

Sulfonate esters are subject to the same limitations as alkyl halides Competition from elimination needs to be considered when planning a functional group transforma tion that requires an anionic nucleophile because tosylates undergo elimination reactions just as alkyl halides do... 

Laboratory syntheses of conjugated dienes can be achieved by elimination reactions of unsaturated alcohols and alkyl halides In the two examples that follow the conjugated diene is produced m high yield even though an isolated diene is also possible... 

Synthesis. The first hiUy alkyl/aryl-substituted polymers were reported in 1980 via a condensation—polymeri2ation route. The method involves, first, the synthesis of organophosphine-containing alkyl or aryl substituents, followed by the ready oxidation of the phosphine to a phosphorane with leaving groups suitable for a 1,2-elimination reaction. This phosphorane is then thermally condensed to polymers in which all phosphoms atoms bear alkyl or aryl substituents. This condensation synthesis is depicted in Eigure 2 (5—7,64). 

Enby 6 is an example of a stereospecific elimination reaction of an alkyl halide in which the transition state requires die proton and bromide ion that are lost to be in an anti orientation with respect to each odier. The diastereomeric threo- and e/ytAra-l-bromo-1,2-diphenyl-propanes undergo )3-elimination to produce stereoisomeric products. Enby 7 is an example of a pyrolytic elimination requiring a syn orientation of die proton that is removed and the nitrogen atom of the amine oxide group. The elimination proceeds through a cyclic transition state in which the proton is transferred to die oxygen of die amine oxide group. 

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. 

Just as the chemistry of alkenes is dominated by addition reactions, the preparation of alkenes is dominated by elimination reactions. Additions and eliminations are, in many respects, two sides of the same coin. That is, an addition reaction might involve the addition of HBr or H20 to an alkene to form an alkyl halide or alcohol, whereas an elimination reaction might involve the loss of HBr or H20 from an alkyl halide or alcohol to form an alkene. 

The two most common elimination reactions arc dehydroUalogenalion—the loss of HX from an alkyl halide—and dehydration—(he loss of water from an alcohol. Dehydrohalogenation usually occurs by reaction of an alkyl halide with strong base such as potassium hydroxide. For example, bromocvclohexane yields cyclohexene when treated with KOH in ethanol solution. 

Alkenes are generally prepared by an elimination reaction, such as dehydrohalo-genation, the elimination of FIX from an alkyl halide, or dehydration, the elimination of water from an alcohol. 

Alkyl halides are encountered less frequently than their oxygen-containing relatives alcohols and ethers, but some of the kinds of reactions they undergo—nucleophilic substitutions and eliminations—are encountered frequently. Thus, alkyl halide chemistry acts as a relatively simple model for many mechanistically similar but structurally more complex reactions found in biornolecules. We ll begin in this chapter with a look at how to name and prepare alkyl halides, and we ll see several of their reactions. Then in the following chapter, we ll make a detailed study of the substitution and elimination reactions of alkyl halides—two of the most important and well-studied reaction types in organic chemistry. 

Elimination Reactions of Alkyl Halides Zaitsev s Rule 383... 

According to Zaitsev s rule, formulated in 1875 by the Russian chemist Alexander Zaitsev, base-induced elimination reactions generally (although not always) give the more stable alkene product—that is, the alkene with more alkyl substituents on the double-bond carbons. In the following two cases, for example, the more highly substituted alkene product predominates. 

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