Electrophilic aromatic substitutions table

Section 12 1 On reaction with electrophilic reagents compounds that contain a ben zene ring undergo electrophilic aromatic substitution Table 12 1 m Section 12 1 and Table 12 3 m this summary give examples... 

Substituent Effects in Electrophilic Aromatic Substitution (Table 12 2, p 464)... 

In most of their- reactions phenols behave as nucleophiles, and the reagents that act on them are electrophiles. Either the hydroxyl oxygen or the aromatic ring may be the site of nucleophilic reactivity in a phenol. Reactions that take place on the ring lead to electrophilic aromatic substitution Table 24.4 summarizes the behavior of phenols in reactions of this type. 

Exercise 22-24 Draw the structures of the intermediate cations for nitration of nitrobenzene in the 2, 3, and 4 positions. Use the structures to explain why the nitro group is meta-orienting with deactivation. Use the same kind of arguments to explain the orientation observed with —CF3, —CHO, —CH2Ci, and —NH2 groups in electrophilic aromatic substitution (Table 22-6),... 

In the absence of desilylation the -SiMe3 group is very slightly activating with no discernable directing effect to electrophilic aromatic substitution (Table 9). 

Notice that the strongly electron-withdrawing nitro substituent that activates the benzene ring toward nucleophilic aromatic substitution, deactivates the ring toward electrophilic aromatic substitution (Table 19.1). hi other words, making the ring less electron rich makes it more reactive toward a nucleophile but less reactive toward an electrophile. 

The scope of electrophilic aromatic substitution is quite large both the aromatic com pound and the electrophilic reagent are capable of wide variation Indeed it is this breadth of scope that makes electrophilic aromatic substitution so important Elec trophilic aromatic substitution is the method by which substituted derivatives of benzene are prepared We can gam a feeling for these reactions by examining a few typical exam pies m which benzene is the substrate These examples are listed m Table 12 1 and each will be discussed m more detail m Sections 12 3 through 12 7 First however let us look at the general mechanism of electrophilic aromatic substitution... 

With this as background let us now examine each of the electrophilic aromatic substitution reactions presented m Table 12 1 m more detail especially with respect to the electrophile that attacks benzene... 

Returning to Table 12 2 notice that halogen substituents direct an incoming electrophile to the ortho and para positions but deactivate the ring toward substitution Nitration of chlorobenzene is a typical example of electrophilic aromatic substitution m a halobenzene... 

The two mam methods for the preparation of aryl halides halogenation of arenes by electrophilic aromatic substitution and preparation by way of aryl diazomum salts were described earlier and are reviewed m Table 23 2 A number of aryl halides occur natu rally some of which are shown m Figure 23 1... 

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... 

Table 10.4. Selectivity in Some Electrophilic Aromatic Substitution Reactions ...

The table below gives first-order rate constants for reaction of substituted benzenes with w-nitrobenzenesulfonyl peroxide. From these data, calculate the overall relative reactivity and partial rate factors. Does this reaction fit the pattern of an electrophilic aromatic substitution If so, does the active electrophile exhibit low, moderate, or high substrate and position selectivity ... 

Table 12.2 summarizes orientation and rate effects in electrophilic aromatic substitution reactions for a variety of frequently encountered substituents. It is arianged in order of decreasing activating power the most strongly activating substituents are at the top, the most strongly deactivating substituents are at the bottom. The main features of the table can be summarized as follows ... 

Phenol and anisole are among the commonly encountered benzene derivatives listed in Table 11.1. Electrophilic aromatic substitution in phenol is discussed in more detail in Section 24.8. 

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 ... 

The reactivity of pyridine relative to that of benzene has been measured using the competitive technique developed by Ingold and his schoool for corresponding studies of electrophilic aromatic substitution. The validity of the method applied to free-radical reactions has been discussed. Three sources of the phenyl radical have been used the results obtained are set out in Table II. 

A Summary of Substituent Effects in Aromatic Substitution A summary of the activating and directing effects of substituents in electrophilic aromatic substitution is shown in Table 16.2. 

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