Electrophiles electron-withdrawing group

The electrophilicity of C = C double bonds conjugated with electron withdrawing groupings leads to a -synthons. This is an important example of the vinyiogous principle ... 

A tertiary carbonium ion is more stable than a secondary carbonium ion, which is in turn more stable than a primary carbonium ion. Therefore, the alkylation of ben2ene with isobutylene is much easier than is alkylation with ethylene. The reactivity of substituted aromatics for electrophilic substitution is affected by the inductive and resonance effects of a substituent. An electron-donating group, such as the hydroxyl and methyl groups, activates the alkylation and an electron-withdrawing group, such as chloride, deactivates it. 

NH form e.g. 505). Most 4- and 5-hydroxy compounds of types (500) and (502) exist largely in these non-aromatic azolinone forms, although the hydroxyl form can be stabilized by chelation e.g. 506). The derived ambident anions react with electrophiles at O or C. Replacement of the hydroxyl group is sometimes possible provided electron-withdrawing groups are present as, for example, in 5-substituted 4-hydroxypyrazoles. 

Since an electron-withdrawing group such as ethoxycarbonyl at the a-carbon atom enhanced the electrophilicity of the )3-carbon atom, the reaction of a-ethoxycarbonyl-)3-ethoxyvinyl ketones (298) with hydroxylamine hydrochloride gave solely 5-substituted isoxazole-4-carboxylates (299) (55JOC1342, 59YZ836). 

Similarly, carboxylic acid and ester groups tend to direct chlorination to the / and v positions, because attack at the a position is electronically disfavored. The polar effect is attributed to the fact that the chlorine atom is an electrophilic species, and the relatively electron-poor carbon atom adjacent to an electron-withdrawing group is avoided. The effect of an electron-withdrawing substituent is to decrease the electron density at the potential radical site. Because the chlorine atom is highly reactive, the reaction would be expected to have a very early transition state, and this electrostatic effect predominates over the stabilizing substituent effect on the intermediate. The substituent effect dominates the kinetic selectivity of the reaction, and the relative stability of the radical intermediate has relatively little influence. 

The reactions of electrophilic alkenes (alkenes attached to electron-withdrawing groups) with enamines produce one or more of the following products simple alkylation (2), 1,2 cycloaddition (3), and 1,4 cycloaddition (4). Competition with C alkylation by N alkylation is inconsequential and therefore will be largely ignored (5,7). A stepwise ionic mechanism leading to these products necessarily involves the formation of a zwitterion intermediate (1) as the first step, which is then followed either by one of the... 

Olefins conjugated with electron-withdrawing groups other than a carbonyl group undergo reactions with enamines in a manner similar to the carbonyl-conjugated electrophilic alkenes described above. Namely, they condense with an enamine to form a zwitterion intermediate from which either 1,2 cycloaddition to form a cyclobutane ring or simple alkylation can take place. 

Terminal alkynes with no electron-withdrawing group next to the acetylenic linkage when treated with enamines merely add across the double bonds of the enamines (9i). But electrophilic alkynes (those with an electron-withdrawing group next to the acetylenic linkage) undergo cycloaddition reactions with enamines. 

In carbohydrates in which benzyl groups are used extensively for protection, the stability of the benzyl groups toward electrophilic reagents is increased by the presence of electron-withdrawing groups in the ring." ... 

Electron-donor substituents are known to accelerate the rate of electrophilic substitution on benzene, while electron-withdrawing groups are known to retard the reaction. One explanation is that electron donors stabilize the positive charge in the benzenium ion intermediate while electron-withdrawing substituents destabilize the positive charge. 

Naphthyridines are (just as pyridines) characterized as 7r-deficient systems. Introduction of an electron-withdrawing group such as the nitro group further depletes the ring of its 7r-electrons and lowers its electron density. On account of this low electron density, nitronaphthyridines show a high reactivity to nucleophilic reagents and low reactivity to electrophiles several characterictic examples of this behavior are shown in this chapter. 

The reaction starts with the nucleophilic addition of a tertiary amine 4 to the alkene 2 bearing an electron-withdrawing group. The zwitterionic intermediate 5 thus formed, has an activated carbon center a to the carbonyl group, as represented by the resonance structure 5a. The activated a-carbon acts as a nucleophilic center in a reaction with the electrophilic carbonyl carbon of the aldehyde or ketone 1 ... 

The reactivity of the phosphorus ylide 1 strongly depends on substituents R R. For preparative use R often is a phenyl group. When R or R is an electron-withdrawing group, the negative charge can be delocalized over several centers, and the reactivity at the ylide carbon is reduced. The reactivity of the carbonyl compound towards addition of the ylide increases with the electrophilic character of the C=0 group. R R are often both alkyl, or alkyl and aryl. 

Most electrophilic substitutions in benzimidazole (31 R = H) occur primarily in the 5-position. In multiple bromination the order followed, 5 > 7 > 6,4 > 2, parallels molecular orbital calculations. In benzimidazole itself the 4(7)- and 5(6)-positions are tautomerically equivalent. Fusion of a benzene ring deactivates C-2 to electrophilic attack to such an extent that it is around 5000 times less reactive than the 2-position of imidazole. Strong electron donors at C-5 direct halogenation to the 4-position, whereas electron-withdrawing groups favor C-4 or C-6 substitution (84MI21). 

Just as electrophilic aromatic substitutions were found more or less to follow the Hammett relationship (with a" " instead of o see p. 692), so do nucleophilic substitutions, with cr instead of a for electron-withdrawing groups. ... 

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