REARRANGEMENT OF N-SUBSTITUTED AROMATIC AMINES

A large number of rearrangement reactions of N-substituted aromatic amines are known apart from the five examples already discussed. In LXII... 

N-Nitro substituted aromatic amines (XXXII) readily undergo rearrangement in the presence of mineral acids or Lewis acids in a variety of solvents and at temperatures around room temperature to give mainly ortho (XXXIII) but also in many cases significant amounts of the para (XXXIV) nitroamine. The reaction... 

Rhodium(II) acetate catalyzes C—H insertion, olefin addition, heteroatom-H insertion, and ylide formation of a-diazocarbonyls via a rhodium carbenoid species (144—147). Intramolecular cyclopentane formation via C—H insertion occurs with retention of stereochemistry (143). Chiral rhodium (TT) carboxamides catalyze enantioselective cyclopropanation and intramolecular C—N insertions of CC-diazoketones (148). Other reactions catalyzed by rhodium complexes include double-bond migration (140), hydrogenation of aromatic aldehydes and ketones to hydrocarbons (150), homologation of esters (151), carbonylation of formaldehyde (152) and amines (140), reductive carbonylation of dimethyl ether or methyl acetate to 1,1-diacetoxy ethane (153), decarbonylation of aldehydes (140), water gas shift reaction (69,154), C—C skeletal rearrangements (132,140), oxidation of olefins to ketones (155) and aldehydes (156), and oxidation of substituted anthracenes to anthraquinones (157). Rhodium-catalyzed hydrosilation of olefins, alkynes, carbonyls, alcohols, and imines is facile and may also be accomplished enantioselectively (140). Rhodium complexes are moderately active alkene and alkyne polymerization catalysts (140). In some cases polymer-supported versions of homogeneous rhodium catalysts have improved activity, compared to their homogenous counterparts. This is the case for the conversion of alkenes direcdy to alcohols under oxo conditions by rhodium—amine polymer catalysts... 

See [6]. The following reaction types have been listed (a) Geometric isomerization of alkenes (b) Allylic [1,3] hydrogen shift (c) Cycloaddition of alkenes. Dimerization, Tri-merization. Polymerization (d) Skeletal rearrangments of alkenes and methathesis (e) Hydrogenation of alkenes (f) Additions to alkenes (g) Additions to C = X (h) Aliphatic substitutions (i) Aromatic substitution (j) Vinyl substitution (k) Oxidation of alkenes (1) Oxidation of alcohols (m) Oxidation of arenes (n) Oxidative decarboxylation (o) Oxidation of amines (p) Oxidation of vinylsilanes and sulfides (q) Oxidation of benzal-dehyde (r) Dehydrogenations. 

A one-pot procedure was developed for the preparation of aromatic amines from phenols via a one-pot Smiles rearrangement by N.P. Peet et al.° This new approach can be considered as an alternative of the Bucherer reaction which only works well for naphthalene derivatives and gives very poor yields for substituted benzene derivatives. In the current procedure, the phenol was reacted with 2-bromo-2-methylpropionamide to give 2-aryloxy-2-methylpropionamide which upon treatment with base underwent the Smiles rearrangement. The hydrolysis of the resulting A/-aryl-2-hydroxypropionamide afforded the aromatic amine. 

Kinetics of reacting I R = H, OMe with nucleophiles such as the enol of pentan-2,4-dione aromatic amines , phosphorus derivatives and some reactive aromatic compounds , and relative rates with substituted (cyclohexadienyl)Fe(GO)3 cation have been examined. These behave as classically expected, but in contrast to 1-or 2-OMe, a 3-OMe increases rate through its inductive effect. The kinetics agree with electrophilic substitution with the possible intermediacy of n complexes " . Because aryl (N-diene)Fe(CO)3 complexes can rearrange by dissociation into C-aryl derivatives", intermediates could also involve reaction with an N of an indole or a MeO (oxonium cation) of MeO-aromatics. 

The reaction of many aromatic amines with nitric acid in concentrated sulphuric acid is well known to give C-nitro products but whether this is a direct C-substitution or an N-substitution followed by rearrangement is usually unknown. The currently accepted view (1) appears to be that nitramine intermediates are seldom involved this conclusion is based on the marked difference in the product compositions obtained in the nitration of aniline and the rearrangement of phenylnitramine when both reactions are carried out in 85% sulphuric acid (2). 

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