1-Arylazo

Mit Diazonium-Salzen findet eine Azokupplung zu 1-Arylazo-benzimidazolen statt454. 

Diese Methode, bei der 1-Arylazo-l-alkene gebildet werden, ist bereits in Bd.X/3, S. 471 If. behandelt worden (s.a. Bd. E15). 

Arylazo-alkyl)-N, N-bis-[kaliumsulfo]- IV/la, 895 N-Aryl-N-terf.-butyl- El6a, 137 (R-NO + R-M) N-Aryl-O-(diphenylphosphinyl)-E16a, 603 (Amin 4- Hydroxyi-amin)... 

Amine 32 was obtained on interaction of compound 14 (R = Ph) with hydrazine closure of the pyrazine ring and withdrawing of the phthaloyl protection are simultaneous processes. Photolysis or thermolysis of 1-arylazo-8-azidonaphthalenes gives rise to benzole, J]indazole N-arylim-ines (78JOC2508 [Eq. (8)]. As a result of a complicated photochemical rearrangement, isoxazolo[5,4-fe]pyridine derivative (33) is converted to N-aminopyrazole 34 in 60% yield (88H1899). 

The synthesis of monosubstituted A -l,2,3-triazolines from 1-arylazo-aziridines (11.1-5) has been reported to give excellent yields (Eq. 9). The starting materials (11.1-5) are often unstable and were isomerized without purification. A more recent report provides a promising alternative and extension for the synthesis of these compounds from dimethyloxosulfonium methylide (11.1-7) (Eq, 10). The use of 4-nitrophenyl- or benzoyl azide produced only triazenes. ... 

The reaction is very common in pyrazolone chemistry. Since alkoxypyrazoles and tautomerizable pyrazolones undergo this reaction and 3-pyrazolin-5-ones, like antipyrine, do not, it is assumed that the reaction takes place at C-4 of the OH tautomer. Pyrazolone diazo coupling is an important industrial reaction since the resulting azo derivatives are used as dyestuffs. For instance, tartrazine (Section 4.04.4.1.3) has been prepared this way. 3,5-Pyrazolidinediones react with aryldiazonium salts resulting in the introduction of a 4-arylazo group. As has been described in Section 4.04.2.1.4(v), diazonium salts couple in the 3-position with indazole to give azo compounds. 

Arylazo-5-pyrazolones are very common products (139 Section 4.04.1.5.2) readily converted into 4-arylazopyrazoles (466 R =H) via the 5-chloro derivatives (466 = Cl)... 

Coumarin, 7-amino-7-(diethylamino)-, I, 333 Coumarin, 7-amino-4-methyl-fluorescence spectra, 3, 601 Coumarin, 7-amino-3-phenyl-brightening agents, I, 339 Coumarin, 4-aryl-occurrence, 3, 677 synthesis, 3, 810 Coumarin, 3-arylazo-4-hydroxy-structure, 3, 643 Coumarin, 3-bromo-reactions... 

Jap-KIingermarm reactions, 4, 301 oxidation, 4, 299 reactions, 4, 299 synthesis, 4, 362 tautomerism, 4, 38, 200 Indole, 5-amino-synthesis, 4, 341 Indole, C-amino-oxidation, 4, 299 tautomerism, 4, 298 Indole, 3-(2-aminobutyl)-as antidepressant, 4, 371 Indole, (2-aminoethyl)-synthesis, 4, 278 Indole, 3-(2-aminoethyl)-synthesis, 4, 337 Indole, aminomethyl-reactions, 4, 71 Indole, 4-aminomethyl-synthesis, 4, 150 Indole, (aminovinyl)-synthesis, 4, 286 Indole, 1-aroyl-oxidation, 4, 57 oxidative dimerization catalysis by Pd(II) salts, 4, 252 Indole, 1-aroyloxy-rearrangement, 4, 244 Indole, 2-aryl-nitration, 4, 211 nitrosation, 4, 210 synthesis, 4, 324 Indole, 3-(arylazo)-rearrangement, 4, 301 Indole, 3-(arylthio)-synthesis, 4, 368 Indole, 3-azophenyl-nitration, 4, 49 Indole, 1-benzenesulfonyl-by lithiation, 4, 238 Indole, 1-benzoyl photosensitized reactions with methyl acrylate, 4, 268 Indole, 3-benzoyl-l,2-dimethyl-reactions... 

Indole-2-carboxylic acid, 3-(arylazo)-ethyl ester... 

Isoxazole-5-thione, 4-arylazo-3-methyl-tautomerism, 6, 57 Isoxazole-5-thiones tautomerism, 6, 11 Isoxazole-3,4,5-tricarboxylic acid esters... 

Boulton-Katritzky rearrangement, 5, 258 Pyrazol-5-one, 4-arylazo-reactions, 5, 262 Pyrazol-5-one, 4-arylidene-configuration, 5, 208... 

Pyrimidine, I-alkyl-2-methyltetrahydro-C-thioacylation, 4, 807 Pyrimidine, 4-alkylsulfinyl-nucleophilie displaeement reaetions, 3, 97 Pyrimidine, 6-alkylsulfinyl-nucleophilic displacement reactions, 3, 97 Pyrimidine, 2-alkylsulfonyl-nueleophilie displaeement reactions, 3, 97 Pyrimidine, 4-alkylsulfonyl-nucleophilic displacement reactions, 3, 97 Pyrimidine, 6-alkylsulfonyl-nucleophilie displaeement reactions, 3, 97 Pyrimidine, alkylthio-dealkylation, 3, 95 desulfurization, 3, 95 oxidation, 3, 96 synthesis, 3, 135, 136 Pyrimidine, 2-alkylthio-aminolysis, 3, 96 hydrolysis, 3, 95 Prineipal Synthesis, 3, 136 Pyrimidine, 4-alkylthio-aminolysis, 3, 96 hydrolysis, 3, 95 Pyrimidine, 6-alkylthio-aminolysis, 3, 96 hydrolysis, 3, 95 Pyrimidine, 4-allenyloxy-rearrangement, 3, 93 Pyrimidine, 4-allyloxy-2-phenyl-rearrangement, 3, 93 Pyrimidine, 4-allynyloxy-rearrangement, 3, 93 Pyrimidine, 4-anilino-2,5,6-trifluoro-NMR, 3, 63 Pyrimidine, 2-aryl-pyrroleaeetic aeid from, 4, 152 Pyrimidine, arylazo-synthesis, 3, 131 Pyrimidine, 4-arylazo-reduetion, 3, 88... 

Pyrimidine, 5-arylazo-reduction, 3, 88 Pyrimidine, aryloxy-hydrolysis, 3, 91 Pyrimidine, arylthio-desulfurization, 3, 95 Pyrimidine, azido-reactions, 3, 82... 

Thiazolin-5-one, 2-alkoxy-4-arylazo-rearrangements, 5, 777 2-Thiazolin-5-one, 4-methyl-2-phenyl-protomeric equilibrium, 6, 249 4-Thiazolin-2-one, 4-aryl-reactions, 6, 286 4-Thiazolin-2-one, 3,4-dimethyl-protonation, 6, 286 4-Thiazolin-2-one, 4-methyl-reactions, 6, 286 Thiazolinones electrophilic attack, 5, 99 Thiazolin-2-ones IR spectroscopy, 6, 241 nucleophilic displacement, 5, 100 2-Thiazolin-4-ones reactions, 6, 287 2-substituted synthesis, 6, 306 synthesis, 5, 129 6, 309, 310 tautomerism, 6, 248 2-Thiazolin-5-ones IR spectroscopy, 6, 242 reactions, 6, 288 synthesis, 5, 138 tautomerism, 6, 249 4-Thiazolin-2-ones synthesis, 6, 314 4-Thiazolin-3-ylacetic acid esters... 

It is interesting to note that whereas 7-methoxy-l-methyl-l,2,3,4-tetrahydro-jS-carboline condenses with diazobenzenesulfonic acid to give an azo compound (presumably the 6-arylazo derivative) and 7-methoxy-l-methyl-3,4-dihydro-j8-carbohne gives a bisazo compound, none of the fully aromatic j8-carboline derivatives studied by Perkin and Robinson underwent azo-coupling. 

Arylazo-2-phenyl-5-oxazolone (30) is converted into the 1,2,4-triazole 31 by the action of phenylmagnesium bromide [Eq. (20)]. 

The conversion of a 4-arylazo-5-oxazolone into a 1,2,4-triazole by reaction with a Grignard reagent is mentioned in Section II, B, 3. In HiTnilar fashion, the rearrangement of compound 30 to derivatives of 3-carboxy-l,5-diphenyl-lfl -l,2,4-triazoles (40) proceeds readily in the presence of strong nucleophiles [Eq. (26)]. This transformation undoubtedly occurs by ring opening and dehydrative cychzation, and, indeed, the acyclic amide and hydrazide 41 have been isolated. ... 

Oxidation of 5-arylazo-6-aminoquinoline 146 with copper sulfate in pyridine gave the corresponding 2-aryltriazolo[4,5-/]quinolines 147. Condensation of halo-genated nitrobenzenes with triazolo[4,5-/]quinoline 145 yielded the appropriate 2H- and 3//-aryl derivatives. The nitration of 3-phenyl-3//-triazolo[4,5-/]quino-line 147 occurred at position 4 of the phenyl ring (Scheme 46) (73T221). 

Ravindranath and co-workers studied the electrochemical behavior of 5-amino-2-phenyl-4-arylazo-l,2-dihydro-3//-pyrazol-3-one (90UC864) and 5-methyl-4-arylazo-2-(pyridin-2-ylcarbonyl)-2,4-dihydro-3//-pyrazol-3-(Mie (90IJC895). Similar studies were undertaken by Jain and Damodharan of pyrazol-3-ones 408a-f (95CJC176) (Scheme 94). The underlying rationale for this study on the electrochemical reduction of these biologically important pyrazol-3-ones is that it can lead to information on the reaction routes and mechanisms of biological redox reactions. 

The ionization of alkyl (E)-arylazo ethers is subject to general acid catalysis when the reaction is carried out in the presence of carboxylic acid buffers (see Scheme 6-3), and the ionization is also subject to steric acceleration in the presence of bulky substituents ortho to the azo ether group (Broxton and Stray, 1980 Broxton and McLeish, 1983 a, and earlier work of Broxton s group). 

The replacement of an electrofugic atom or group at a nucleophilic carbon atom by a diazonium ion is called an azo coupling reaction. By far the most important type of such reactions is that with aromatic coupling components, which was discovered by Griess in 1861 (see Sec. 1.1). It is a typical electrophilic aromatic substitution, called an arylazo-de-hydrogenation in the systematic IUPAC nomenclature (IUPAC 1989c, see Sec. 1.2). 

There are also some couplings in which hydrazones are formed but for which the azo tautomer is not detectable and probably does not exist. This is the case in some coupling reactions involving methyl groups of aromatic heterocycles (see, for example, 12.48 and 12.49 in Sec. 12.5). Replacement of a methyl proton by an arylazo group (Scheme 12-3) would result in an azo compound containing an sp3-hybridized — CH2 — group (12.1). The latter is less stable than the tautomeric hydrazone (12.2), in which there is a n-n orbital overlap from the heteroaromatic to the aromatic system. 

A novel result of azo coupling was observed by Bagal et al. (1992 a) when they reacted 4-phenylazophenol and its 2-methyl derivative with an excess of 4-nitroben-zenediazonium salt. They obtained a compound whose elemental analysis and H NMR, UV, and IR spectra are consistent with 4,4-bis(4 -nitrophenylazo)-cyclohexa-2,5-dienone (12.14). The replacement of an arylazo group by a more electrophilic diazonium ion had occasionally been observed before this, but the double azo coupling in the 4-position is new. 

Azo coupling reactions with phenol ethers give in some cases the expected arylazo-phenol ether. In others, however, hydrolysis of the ether bond is observed and the arylazophenol is isolated. This ambiguity has, to the best of our knowledge, never been investigated systematically. 

Non-benzenoid aromatic compounds containing a hydroxy group also react with arenediazonium ions and form arylazo derivatives. The first case of such an azo coupling process was found by Nozoe (1949) in his classic work on the natural product hinokitiol (12.15, R=CH3 Nozoe, 1959, 1991). Shortly afterwards Nozoe et al. 

The triphenylsilyl leaving group in 12.29 is interesting from a mechanistic viewpoint (Sunthankar and Gilman, 1950), as also is the replacement of the nitro group in l-nitro-2-naphthol by an arylazo group (Bunce, 1974). 

The azo coupling reaction of the calix[4]arene 12.32 shows an unexpected auto-catalytic effect. If the molar ratio of the diazonium ion (X=N02) to the calix[4]arene is 4 1, the yield of the tetra(arylazo)calix[4]arene 12.33 is 99%, but with ratios 3 1, 2 1, and 1 1 the tetra(arylazo) compound is also a major product (70%, 45%, and 22% respectively). If ratios 3 1, 2 1, and 1 1 are used the yields of the tris- and bis(arylazo) products are in the range of only 1.2-3.4%, and the mono(arylazo) compound is formed with a yield of 5.3-6.0%. Using the ratio 4 1 the bis- and mono(arylazo) products are not found at all, and the tris(arylazo) com-... 

The coupling reaction of 3-methylindole (Scheme 12-21) is complex, as it involves an initial ipso-addition at the 3-position followed by rearrangement of the arylazo group to the 2-position (Jackson and Lynch, 1987 Jackson et al., 1987). However, under slightly different conditions Spande and Glenner (1973) isolated the unusual triazene 12.41. Based on the change in the UV spectrum of the reaction mixture with time, Sarma and Barooah (1977) proposed a mechanism involving initial formation... 

With l,l-bis(4, 4"-dialkylamino)phenylethene (12.105) azo coupling takes place in the 2-position (Wizinger and Cyriax, 1945, 1957). Deprotonation of the primary adduct to give the red l,l-bis(dialkylaminophenyl)-2-arylazo-ethene 12.106 takes place rapidly after addition of a sodium ethoxide solution (Scheme 12-53). 

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