Activating groups, aromatic substitution

Acifluorfen, synthesis of, 683 Acrolein, structure of, 697 Acrylic acid, pKa of, 756 structure of. 753 Activating group (aromatic substitution), 561 acidity and, 760 explanation of, 564-565 Activation energy, 158 magnitude of, 159 reaction rate and, 158-159 Active site (enzyme), 162-163 citrate synthase and, 1046 hexokinase and, 163... 

Finally, the azido group would be expected to activate homolytic aromatic substitution by virtue of its ability to provide additional stabilization to free radical intermediates. No evidence in support of this prediction is available however and investigation in this area seems warranted. 

I.S. Chung, S.Y Kim, Meta-activated nucleophilic aromatic substitution reaction poly(biphenylene oxide)s with trifluoromethyl pendent groups via nitro displacement, J. Am. Chem. Soc. 123 (44) (2001) 11071-11072. 

Protecting the amino group of an arylamine in this way moderates its reactivity and per mits nitration of the ring to be achieved The acetamido group is activating toward elec trophilic aromatic substitution and is ortho para directing... 

A nitro group is a strongly activating substituent in nucleophilic aromatic substitution where it stabilizes the key cyclohexadienyl anion intermediate... 

The hydroxyl group of a phenol is a strongly activating substituent and electrophilic aromatic substitution occurs readily m phenol and its deriv atives Typical examples were presented m Table 24 4... 

The aromatic nucleus of alkylphenols can undergo a variety of aromatic electrophiUc substitutions. Electron density from the hydroxyl group is fed iato the ring. Besides activating the aromatic nucleus, the hydroxyl group controls the orientation of the incoming electrophile. 

Electrophilic substitution reactions of diarylamines are easily accompHshed since the amino group activates the aromatic ring. Thus, DPA reacts with bromine or chlorine to form the 2,2H,4 tetrahalo derivative nitration usually produces the trinitro compound. 

Resonance effects are the primary influence on orientation and reactivity in electrophilic substitution. The common activating groups in electrophilic aromatic substitution, in approximate order of decreasing effectiveness, are —NR2, —NHR, —NH2, —OH, —OR, —NO, —NHCOR, —OCOR, alkyls, —F, —Cl, —Br, —1, aryls, —CH2COOH, and —CH=CH—COOH. Activating groups are ortho- and para-directing. Mixtures of ortho- and para-isomers are frequently produced the exact proportions are usually a function of steric effects and reaction conditions. 

A hydroxyl group is a very powerful activating substituent, and electrophilic aromatic substitution in phenols occurs far- faster, and under milder conditions, than in benzene. The first entry in Table 24.4, for exfflnple, shows the monobromination of phenol in high yield at low temperature and in the absence of any catalyst. In this case, the reaction was carried out in the nonpolar- solvent 1,2-dichloroethane. In polar- solvents such as water it is difficult to limit the bromination of phenols to monosubstitution. In the following exfflnple, all three positions that are ortho or para to the hydroxyl undergo rapid substitution ... 

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