Electrophilic aromatic deactivation

Why IS there such a marked difference between methyl and trifluoromethyl substituents m their influence on electrophilic aromatic substitution s Methyl is activating and ortho para directing trifluoromethyl is deactivating and meta directing The first point to remember is that the regioselectivity of substitution is set once the cyclohexadienyl cation intermediate is formed If we can explain why... 

Table 12 2 summarizes orientation and rate effects m electrophilic aromatic sub stitution reactions for a variety of frequently encountered substituents It is arranged m order of decreasing activating power the most strongly activating substituents are at the top the most strongly deactivating substituents are at the bottom The mam features of the table can be summarized as follows... 

Substituent Effects in Electrophilic Aromatic Substitution Strongly Deactivating Substituents... 

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... 

Electrophilic aromatic substitution (Section 12 14) Halo gen substituents are slightly deactivating and ortho para directing Br... 

Deactivating substituent (Sections 12 11 and 12 13) A group that when present in place of hydrogen causes a particular reaction to occur more slowly The term is most often ap plied to the effect of substituents on the rate of electrophilic aromatic substitution... 

Whereas the above reactions are appHcable to activated aromatics, deactivated aromatics can be formylated by reaction with hexamethylenetetramine in strong acids such as 75% polyphosphoric acid, methanesulfonic acid, or trifluoroacetic acid to give saUcylaldehyde derivatives (117). Formyl fluoride (HCOF) has also been used as formyl a ting agent in the Friedel-Crafts reaction of aromatics (118). Formyl fluoride [1493-02-3] in the presence of BF was found to be an efficient electrophilic formyl a ting agent, giving 53% para-, 43% ortho- and 3.5% meta-tolualdehydes upon formylation of toluene (110). 

Adivating/Deactivating Effects on Electrophilic Aromatic Substitution... 

The pKa of p-(tiifluoromethyl)benzoic acid is 3.6. Is the trifluoromethyl substituent an activating or deactivating group in electrophilic aromatic substitution ... 

The pKa s of five p-substituted benzoic acids (YC6H4C02H) follow. Rank the corresponding substituted benzenes (YC Hs) in order of their increasing reactivity toward electrophilic aromatic substitution, if benzoic acid has pK , = 4.19, which of the substituents are activators and which are deactivators ... 

Deactivating group (Section 16.4) An electron-withdrawing substituent that decreases the reactivity of an aromatic ring toward electrophilic aromatic substitution. 

In the discussion of electrophilic aromatic substitution (Chapter 11) equal attention was paid to the effect of substrate structure on reactivity (activation or deactivation) and on orientation. The question of orientation was important because in a typical substitution there are four or five hydrogens that could serve as leaving groups. This type of question is much less important for aromatic nucleophilic substitution, since in most cases there is only one potential leaving group in a molecule. Therefore attention is largely focused on the reactivity of one molecule compared with another and not on the comparison of the reactivity of different positions within the same molecule. 

The Bis A-PSF can be sulfonated on the Bis A residue, but the Bis S-PSF will not sulfonate due to the deactivating effect of -SO2- on electrophilic aromatic substitution. Therefore, such a block copolymer would allow the study of sequence length effects on membrane performance. 

The empirical data for electrophilic aromatic substitution on benzocycloalkenes over a variety of reactions and conditions show a consistent trend of increased Cp selectivity due primarily to C deactivation, with some indication that Cp activation occurs in benzobicycloalkenes. Acidity work on the benzocycloalkenes and related pyridines demonstrates clearly the extent of deactivation. The rehybridization model of Finnegan and Streitweiser has been postulated to account for the deactivation. Thummel s correlation of C y -H P a provided the necessary link between rehybridization and deactivation. Theories involving bond fixation in the Wheland intmnediate deserve some further consideration but are not essential to an understanding of the present empirical data. 

Such a representation is referred to as a local ionization potential map. Local ionization potential maps provide an alternative to electrostatic potential maps for revealing sites which may be particularly susceptible to electrophilic attack. For example, local ionization potential maps show both the positional selectivity in electrophilic aromatic substitution (NH2 directs ortho para, and NO2 directs meta), and the fact that TC-donor groups (NH2) activate benzene while electron-withdrawing groups (NO2) deactivate benzene. 

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