Electron-withdrawing groups nucleophilic substitution

Here, as in electrophilic substitution, the pyridine ring resembles a benzene ring that contains strongly electron-withdrawing groups. Nucleophilic substitution takes place readily, particularly at the 2- and 4-positions. For example ... 

Nucleophilic substitution m ArX is facilitated by the presence of a strong electron withdrawing group such as NO2 ortho or para to the halogen... 

Nucleophilic Substitutions of Benzene Derivatives. Benzene itself does not normally react with nucleophiles such as haUde ions, cyanide, hydroxide, or alkoxides (7). However, aromatic rings containing one or more electron-withdrawing groups, usually halogen, react with nucleophiles to give substitution products. An example of this type of reaction is the industrial conversion of chlorobenzene to phenol with sodium hydroxide at 400°C (8). 

The nucleophilic aromatic substitution reaction for the synthesis of poly(arylene ether ketone)s is similar to that of polysulfone, involving aromatic dihalides and aromatic diphenolates. Since carbonyl is a weaker electron-withdrawing group titan sulfonyl, in most cases, difluorides need to be used to afford high-molecular-weight polymers. Typically potassium carbonate is used as a base to avoid the... 

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. ... 

When aromatic nitro compounds are treated with cyanide ion, the nitro group is displaced and a carboxyl group enters with cine substitution (p. 854), always ortho to the displaced group, never meta or para. The scope of this reaction, called the von Richter rearrangement, is variable. As with other nucleophilic aromatic substitutions, the reaction gives best results when electron-withdrawing groups are in ortho and para positions, but yields are low, usually < 20% and never > 50%. 

Arylations of nitro compounds can be achieved by aromatic nucleophilic substitution using aromatic nitro compounds, as discussed in Chapter 9.100 Komblum and coworkers reported displacement of the nitro group of nitrobenzenes by the anion of nitroalkanes. The reactions are usually carried out in dipolar aprotic solvents such as DMSO or HMPA, and nitroaromatic rings are substituted by a variety of electron-withdrawing groups (see Eq. 5.63).101... 

Nucleophilic substitution of thiophene can also be enabled by the presence of electron withdrawing groups (e.g., -CHO <00SC1359>, -COMe <00T7573>, -NO2 <00JCS(P1)1811>) on carbon. The regioselectivity of the addition of amine nucleophiles onto 3,5-dibromothiophene-2-carboxaldehyde (54) has been studied and found to be independent of reaction conditions (para product 55 favored over ortho product 56) <00SL459>. 

Electronic effects. Nucleophilic attack is favoured by electron-withdrawing groups on the amide and the acyloxyl side chains. Interpolated bimolecular rate constants at 308 K for the series of para-substituted /V-acetoxy-/V-butoxybenzamides 25c, 26b-g and 26i (Table 5) gave a weak but positive Hammett correlation with a constants ip = 0.13, r = 0.86).42,43 These Sn2 reactions are analogous to those of aniline and substituted pyridines with phenacyl bromides, which have similar Arrhenius activation energies and entropies of activation in methanol (EA= 14-16 kcal mol-1, AS = — 27 to —31 calK-1 mol-1) and 4-substituted phenacyl halides afforded a similar Hammett correlation with pyridine in methanol (cr, p — 0.25).175... 

In the literature, there are numerous reports regarding the interactions between amines and both electron and proton acceptors132, but less attention has been devoted to interactions between amines and aromatic electron acceptors, in particular when the substrate/amine system is a reacting system, as in the case of nucleophilic aromatic substitution (SjvAr) reactions between amines and substrates activated by nitro or by other electron-withdrawing groups. 

In an extension of the procedure, thiols react with gem-dihaloalkanes (Table 4.4) to produce thioacetals [ 10,20-23] and the reaction can be employed in the Corey-Seebach synthesis of aldehydes and ketones (see ref. 24 and references cited therein), gem-Dichlorocyclopiopanes having an electron-withdrawing group at the 2-position react with thiols to produce the thioacetals [25]. In the corresponding reaction of the thiols with biomochloromethane exclusive nucleophilic substitution of the bromo group by the thiolate anion occurs to yield the chloromethyl thioethers [13, 14] (Table 4.5). 

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