Electrophilic aromatic substitution reactions categories

Aromatic substituents are broken into two categories regarding electrophilic aromatic substitution reactions activating or deactivating, and ortho/para directing or meta directing. When/n > 1, we say that substituent R is activating, and when< 1, we classify that... 

The mechanisms of the Gattermann and Gattermann-Koch formylation belong to the category of electrophilic aromatic substitution (SEAr) but are not known in detail, since they have a tendency to vary from one substrate to another, and the reaction conditions may also play a role. When carbon monoxide is used, the electrophilic species is believed to be the formyl cation, which is attacked by the aromatic ring to form a -complex. This -complex is then converted to the aromatic aldehyde upon losing a proton. When HCN is used, the initial product after the SEAr reaction is an imine hydrochloride, which is subsequently hydrolyzed to the product aldehyde. 

Indoles are usually constructed from aromatic nitrogen compounds by formation of the pyrrole ring as has been the case for all of the synthetic methods discussed in the preceding chapters. Recently, methods for construction of the carbocyclic ring from pyrrole derivatives have received more attention. Scheme 8.1 illustrates some of the potential disconnections. In paths a and b, the syntheses involve construction of a mono-substituted pyrrole with a substituent at C2 or C3 which is capable of cyclization, usually by electrophilic substitution. Paths c and d involve Diels-Alder reactions of 2- or 3-vinyl-pyrroles. While such reactions lead to tetrahydro or dihydroindoles (the latter from acetylenic dienophiles) the adducts can be readily aromatized. Path e represents a category Iley cyclization based on 2 -I- 4 cycloadditions of pyrrole-2,3-quinodimcthane intermediates. 

In Part 2 of this book, we shall be directly concerned with organic reactions and their mechanisms. The reactions have been classified into 10 chapters, based primarily on reaction type substitutions, additions to multiple bonds, eliminations, rearrangements, and oxidation-reduction reactions. Five chapters are devoted to substitutions these are classified on the basis of mechanism as well as substrate. Chapters 10 and 13 include nucleophilic substitutions at aliphatic and aromatic substrates, respectively, Chapters 12 and 11 deal with electrophilic substitutions at aliphatic and aromatic substrates, respectively. All free-radical substitutions are discussed in Chapter 14. Additions to multiple bonds are classified not according to mechanism, but according to the type of multiple bond. Additions to carbon-carbon multiple bonds are dealt with in Chapter 15 additions to other multiple bonds in Chapter 16. One chapter is devoted to each of the three remaining reaction types Chapter 17, eliminations Chapter 18, rearrangements Chapter 19, oxidation-reduction reactions. This last chapter covers only those oxidation-reduction reactions that could not be conveniently treated in any of the other categories (except for oxidative eliminations). 

Solution N-propylbenzene is a compound made up of aromatic and alkane units. Hence, it belongs in the category of alkylbenzenes, which, in turn, are part of the group of compounds known as arenes (compounds that contain both aliphatic and aromatic units). Such compounds show two sets of chemical properties. The ring undergoes the electrophilic substitution characteristic of benzene, whereas the side chain undergoes the free-radical substitution characteristic of alkanes. Each should modify the other. Except for oxidation and hydrogenation these are the reactions to be expected for arenes. 

Since heteroaromatic compounds sometimes exhibit interesting physical properties and biological activities, construction of substituted heteroaromatics has drawn some attention. Heteroaromatics can be divided into two major categories. One is the tt-electron-sufhcient heteroaromatics, such as pyrrole, indole, furan, and thiophene those easily react with electrophiles. The other is the 7r-electron-deficient heteroaromatics, such as pyridine, quinoline, and isoquinoline those have the tendency to accept the nucleophilic attack on the aromatic ring. Reflecting the electronic nature of heteroaromatics, the TT-electron-deflcient ones are usually used as the electrophiles.t The rr-electron-sufficient heteroaromatics having simple structures, such as 2-iodofuran and 2-iodothio-phene, have also been utilized as the electrophiles. Not only the electronic nature of the heteroaromatics but also coordination of the heteroatom to the palladium complexes influence catalytic activity. This is another reason why the couphng reaction did not proceed efficiently in some cases. 

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