Diarylamines oxidation

Nitroxyl radicals of diarylamines can also be obtained on oxidation with hydrogen peroxide in the presence of vanadium ions. Resonance helps stabili2e these radicals. Eor example, the nitroxide from 4,4 -dimethoxydiphenylainine [63619-50-1] is stable for years, whereas the radical from the unsubstituted diphenylamine caimot be isolated. Substitution in the ortho and para positions also increases the stabiUties of these nitroxides by inhibiting coupling reactions at these sites. However, they are not as stable as the stericaHy hindered tetramethylpiperidyl radical. 

The addition of 2,2, 4,4, 6-pentanitro-6 -methyldiphenylamine [64653-47-0] to seawater precipitates potassium (38). Aromatic amines, especially aminotetrahydronaphthalenes and their A[-aryl derivatives, are efficient flotation agents for quartz. The use of DPA for image formation in films has been patented (39,40). Diarylamines are used as intermediates (41) for azo, sulfur, oxidative base, triaryhnethane, oxazine, nitro, and safranine dyes (see Dyes and DYE INTERLffiDIATES). 

In addition, complexes of P(/-Bu)3 have been shown to catalyze the formation of diaryl heteroarylamines from bromothiophenes.224 Aminations of five-membered heterocyclic halides such as furans and thiophenes are limited because their electron-rich character makes oxidative addition of the heteroaryl halide and reductive elimination of amine slower than it is for simple aryl halides. Reactions of diarylamines with 3-bromothiophenes occurred in higher yields than did reactions of 2-bromothiophene, but reactions of substituted bromothiophenes occurred in more variable yields. The yields for reactions of these substrates in the presence of catalysts bearing P(/-Bu)3 as ligand were much higher than those in the presence of catalysts ligated by arylphosphines. 

The oxidative cyclization of Ar,Ar-diarylamines to carbazoles has been achieved by thermal or photolytic induction [7, 75]. However, the yields for this transformation are mostly moderate. Better results are obtained by the palladium(II)-mediated oxidative cyclization of Ar,Ar-diarylamines (Scheme 27). Oxidative cyclization by heating of the Ar,Ar-diarylamines 76 in the presence of a stoichiometric amount of palladium(II) acetate in acetic acid under reflux provides the corresponding 3-substituted carbazoles 77 in 70-80% yield [118]. The cou-... 

Scheme 27 Palladium(II)-mediated oxidative cyclization ofiSr,iST-diarylamines...

The palladium(II)-mediated oxidative cyclization of Ar,AT-diarylamines is useful for convergent total syntheses of a range of structurally different carbazole alkaloids. Goldberg coupling of 2,3-dimethoxyacetanilide 80 and 2-bromo-5-methylanisole 81 and subsequent alkaline hydrolysis affords the diarylamine 82... 

The Goldberg coupling between 5-acetylamino-2,2-dimethylchromene 84 and 5-bromo-2-methylanisole 85 followed by hydrolysis leads to the diarylamine 86, which on palladium(II)-mediated oxidative cyclization affords pyrayafoline A 87 [ 17] (Scheme 30). Starting from 7-acetylamino-2,2-dimethylchromene, the method has been applied to the synthesis of 0-methylpyrayafoline B [54]. 

Buchwald-Hartwig amination of iodobenzene 92 with 2-benzyloxy-4-methyl-aniline 93 affords the diarylamine 94 in high yield (Scheme 32). In this case the Goldberg coupling gives poor yields. Oxidative cyclization of compound 94 using stoichiometric amounts of palladium(II) acetate in acetic acid under reflux leads to the carbazole 95, which by reductive debenzylation provides... 

Menendez et al. reported the synthesis of murrayafoline A (7) by palladium(II)-mediated oxidative double C-H activation of a diarylamine assisted by microwave irradiation (585). The aniline derivative 598 was obtained by O-methylation of 5-methyl-2-nitrophenol (625) followed by catalytic hydrogenation. The required diarylamine 654 was obtained by N-arylation of the aniline derivative 598 with phenyllead triacetate (653) in the presence of copper(II) acetate. Under microwave-assisted conditions, in the presence of more than the stoichiometric amount of palladium(II) acetate and a trace of dimethylformamide, the diarylamine 654 was cyclodehydrogenated to murrayafoline A (7) (585) (Scheme 5.47). 

The relay compound 1025 required for the synthesis of all of these 7-oxygenated carbazole alkaloids was obtained starting from commercially available 4-bromo-toluene (1023) and m-anisidine (840) in two steps and 72% overall yield. Buchwald-Hartwig amination of 4-bromotoluene (1023) with m-anisidine (840) furnished quantitatively the corresponding diarylamine 1024. Oxidative cyclization of 1024 using catalytic amounts of palladium(ll) acetate afforded 3-methyl-7-methoxycarbazole (1025). Oxidation of 1025 with DDQ led to clauszoline-K (98), which, on cleavage of the methyl ether using boron tribromide, afforded 3-formyl-7-hydroxycarbazole (99) (546) (Scheme 5.149). 

Nitrenium ions can be viewed as products from two-electron oxidation of amines (Fig. 13.13) followed by loss of a proton. Thus they need to be considered as intermediates in the oxidation of amines. In two early studies, diarylnitrenium ions were shown to have formed in the oxidation of diarylamines. Svanholm and Parker carried out cyclic voltammetry on A,A-di-(2,4-methoxyphenyl)amine (25) in acetonitrile with alumina added to suppress any adventitious nucleophiles. The voltam-mogram revealed two sequential oxidation processes (1) formation of the cation radical 26, and (2) either the nitrenium ion 27 or its conjugate acid. In strongly acidic solution the latter was sufficiently stable that its absorption spectrum could be recorded. 

There has been a review of die effects of high pressure on the substitution reactions of amines witii haloaromatic compounds, including polyhalobenzenes.17 Nucleophilic substiditions by amines often proceed readily hi dimethyl sulfoxide (DMSO). The pKa values, hi DMSO, have been reported for some ammonium ions derived from amines widely used as nucleophiles in 5nAt reactions.18 Correlations have been established19 between die oxidation potentials and the basicities of some arylamhie and diarylamine anions and die rate constants for dieir reactions with aiyl halides in DMSO. 

Studies (2, 3) have also been reported of the reaction of phosphorus trichloride with diarylamines containing p-methyl or p-chloro substituents. In every case, the expected ring-substituted derivatives of 1 and 2 were obtained after the reaction mixture was treated with water. The interaction of (V-phenyl-o-toluidine and phosphorus trichloride at 200°C also gave a reaction mixture from which the expected phosphine oxide was isolated (3). None of the corresponding spirophosphonium chloride, however, could be obtained. The failure to isolate this substance can not be explained simply by the presence of an ortho substituent in the diarylamine, since it had been previously found that a 34% yield of a spirophosphonium chloride can be obtained via the interaction of fl/-phenyl-l-naphthylamine and phosphorus trichloride (2). No dihydropheno-phosphazine derivatives at all were obtained by the interaction of di-o-tolylamine and phosphorus trichloride at 200°C (3). 

Aminations of five-membered heterocyclic halides, such as furans and thiophenes, are limited. These substrates are particularly electron-rich. As a result, oxidative addition of the heteroaryl halide and reductive elimination of the amine are slower than for simple aryl halides (see Sections 4.7.1 and 4.7.3). In addition, the amine products can be air-sensitive and require special conditions for their isolation. Nevertheless, Watanabe has reported examples of successful couplings between diarylamines and bromothiophenes [126]. Triaryl-amines are important for materials applications because of their redox properties, and these particular triarylamines should be especially susceptible to electrochemical oxidation. Chart 1 shows the products formed from the amination of bromothiophenes and the associated yields. As can be seen, 3-bromothiophene reacted in higher yields than 2-bromothiophene, but the yields were more variable with substituted bromothiophenes. In some cases, acceptable yields for double additions to dibromothiophenes were achieved. These reactions all employed a third-generation catalyst (vide infra), containing a combination of Pd(OAc)2 and P(tBu)3. The yields for reactions of these substrates were much higher in the presence of this catalyst than they were in the presence of arylphosphine ligands. 

The oxidative cyclization of N,N-diarylamines represents a straightforward alternative route to the carbazole framework [55]. However, application of the classical thermally, photolytically or radical-induced process provides only moderate yields. Much higher yields are obtained for this transformation by palladium(II)-mediated oxidative cyclization, first reported by Akermark (Scheme 15.15) [56]. 

Scheme 15.15 Palladium(ll)-mediated oxidative cyclization of N,N-diarylamines to carbazoles.

Heating of the N,N-diarylamines with palladium(II) acetate in acetic acid at reflux results in smooth oxidative cyclization to the corresponding carbazole derivatives. A variety of substituents are tolerated in different positions. Thus, this procedure has found many applications in organic syntheses [30,55]. However, the drawback is that stoichiometric amounts of palladium(II) are required, as one equivalent of palla-dium(O) is formed in the final reductive elimination step. In the Wacker process, regeneration of the catalytically active palladium(II) species is achieved by oxidation of palladium(O) to palladium(II) with a copper(II) salt [57]. We were the first to demonstrate that oxidative regeneration of the catalytically active palladium(II)... 

Buchwald-Hartwig amination of p-bromotoluene with m-anisidine affords quantitatively the corresponding diarylamine. While oxidative cyclization using stoichiometric amounts of palladium(II) acetate provides only 36 % yield of 7-methoxy-3-methylcarbazole, up to 72 % yield is obtained using catalytic amounts of palladium(II). The highest turnover for the catalytic cycle is obtained with... 

The major pathways for the anodic oxidation of diarylamines are N,N- or aryl,aryl-coupling, A,aryl-coupling, and nucleophilic substitution in the aromatic ring. Which pathway actually will be followed depends on the reaction conditions and the substitution pattern of the substrate. With regard to the latter, one has to distinguish between p-unsubstituted, p-mono- and / -disubstituted diphenylamines. 

Since UV absorbers cannot completely prevent the initiation reactions above, we felt that better antioxidants were necessary to obtain improved long-term photo-oxidative stability of polyolefins. We reasoned that stable radicals which scavenge radicals formed in the oxidative process might compensate for the imperfections of the absorbers. On the basis of the assumption that the diaryl nitroxyl radicals, rather than their parent diarylamines, are the active antifatigue species in rubber protection, we first attempted to obtain new stable nitroxyl radicals. 

This process is very important in the HALS stabilization mechanism. It should, however, be considered only as a minority pathway in diarylamines just because of the lower stability of the corresponding diarylnitroxides. This results in the participation of the latter in side reactions leading to antioxidant ineffective species, e.g. benzoquinone (BQ) and nitrobenzene ( 7 ). Transformation of diarylnitroxide into a mixture of diarylamine and N-aryl-1,4-benzoquinone monoimine-N-oxide (4. 8) seems therefore to be a more probable pathway regenerating partly amine antioxidant than the hydroxylamine/nitroxide cyclical process (Scheme 2). 

In the HPPD ozonation, the free radical chemistry seems to be more important than in DOPPD, due to the stabilizing effect provided by the diarylamine moiety (40). The nitroxide pathway is therefore of relevant importance in HPPH ozonation to amine oxide and side chain oxidation pathways. Because of the influence of N-substituent effects the ozonation of HPPH occurs only on the aliphatic side of the molecule and a nitrone is the most abundant ozonation product. 

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