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Amine oxide formation

The hterature suggests that more than one mechanism may be operative for a given antiozonant, and that different mechanisms may be appHcable to different types of antiozonants. All of the evidence, however, indicates that the scavenger mechanism is the most important. All antiozonants react with ozone at a much higher rate than does the mbber which they protect. The extremely high reactivity with ozone of/)-phenylenediamines, compared to other amines, is best explained by their unique abiUty to react ftee-tadicaHy. The chemistry of ozone—/)-PDA reactions is known in some detail (30,31). The first step is beheved to be the formation of an ozone—/)-PDA adduct (32), or in some cases a radical ion. Pour competing fates for dissociation of the initial adduct have been described amine oxide formation, side-chain oxidation, nitroxide radical formation, and amino radical formation. [Pg.237]

Amide reduction with lithium aluminum hydride, 39, 19 Amine oxide formation, 39, 40 Amine oxide pyrolysis, 39, 41, 42 -Aminoacetanilide, 39, 1 Amino adds, synthesis of, 30, 7 2-Amino-4-anilino-6-(chloro-METHYl) -S-TRIAZINE, 38, 1 -Aminobenzaldehyde, 31, 6 hydrazone, 31, 7 oxime, 31, 7 phenylhydrazone, 31, 7 > -Aminobenzoic add, 36, 95 2-Aminobenzophenone, 32, 8 c-Aminocaproic acid, 32, 13 6-Aminocaproic acid hydrochloride,... [Pg.83]

Azonation of tertiary aliphatic amines has received some attention in recent years. Amine oxide formation was established long ago (1). Oxidation of alkyl groups was reported by Henbest and Stratford (2), Shulman (3), and Bailey et al. (4, 5). Formation of amine hydrochlorides was established when chlorinated solvents were used (2-5). De-alkylated products were formed (2, 4, 5), and amides were found by the same authors (2-5). [Pg.101]

The best known of these is the ozonation of tertiary amines to amine oxides (II) (i). Henbest and Stratford (11) and Shulman (17) have shown that competing with this is an ozone attack on the alpha position of an alkyl side chain to produce various decomposition products of III. Henbest (11) showed that amine oxide formation is favored in chloroform and methanol, while side chain oxidation is predominant in hydrocarbon solvents. Also of considerable interest are the reported conversions, during ozonation, of phenylenediamines to Wursters salts (VII) (8, 14), of liquid ammonia to ammonium ozonate (VA) at a low temperature 18), and of amines to amine hydrochlorides (VB) in chlorinated hydrocarbon solvents 17, 19), Finally, an early report states that azobenzene and quinone are obtained upon ozonation of aniline (15). [Pg.64]

The mechanism of tertiary amine oxide formation has not been studied in detail, but by analogy with primary amines (see above), the reaction must involve attack by the electrophilic peroxidic oxygen on the amine lone pair, foUowed by anion elimination and proton loss (Scheme 24). In accord with this conclusion, the reactions are first... [Pg.170]

The mechanism of amine oxide formation has not been studied closely. The reaction has a first-order dependence on both amine and ozone concentrations and almost certainly involves a slow electrophilic attack by the terminal oxygen on the amine lone-pair electrons (equation 88) as the conjugate acid of the amine is unreactive . [Pg.588]

Amine oxides show either nonionic or cationic behavior in aqueous solution depending on pH. In acid solution the cationic form (R2N" OH) is observed (2) while in neutral and alkaline solution the nonionic form predorninates as the hydrate R NO H2O. The formation of an ionic species in the acidic pH range stabilizes the form generated by the most studied commercial amine oxide, dimethyldodecylamine oxide (6). [Pg.189]

Similarly the active oxygen of oxaziranes can be transferred to triphenylphosphine with the formation of ]ihosphine oxide and to tertiary amines yielding amine oxides. ... [Pg.92]

Like amine oxide elimination, selenoxide eliminations normally favor formation of the E-isomer in acyclic structures. In cyclic systems the stereochemical requirements of the cyclic TS govern the product composition. Section B of Scheme 6.21 gives some examples of selenoxide eliminations. [Pg.599]

The mechanism of H02 formation from peroxyl radicals of primary and secondary amines is clear (see the kinetic scheme). The problem of H02 formation in oxidized tertiary amines is not yet solved. The analysis of peroxides formed during amine oxidation using catalase, Ti(TV) and by water extraction gave controversial results [17], The formed hydroperoxide appeared to be labile and is hydrolyzed with H202 formation. The analysis of hydroperoxides formed in co-oxidation of cumene and 2-propaneamine, 7V-bis(ethyl methyl) showed the formation of two peroxides, namely H202 and (Me2CH)2NC(OOH)Me2 [16]. There is no doubt that the two peroxyl radicals are acting H02 and a-aminoalkylperoxyl. The difficulty is to find experimentally the real proportion between them in oxidized amine and to clarify the way of hydroperoxyl radical formation. [Pg.359]

Hence, the copper surface catalyzes the following reactions (a) decomposition of hydroperoxide to free radicals, (b) generation of free radicals by dioxygen, (c) reaction of hydroperoxide with amine, and (d) heterogeneous reaction of dioxygen with amine with free radical formation. All these reactions occur homolytically [13]. The products of amines oxidation additionally retard the oxidation of hydrocarbons after induction period. The kinetic characteristics of these reactions (T-6, T = 398 K, [13]) are presented below. [Pg.689]

The above sequence mimics the proposed biosynthesis of Ervatamia alkaloids and in this context Thai and Mansuy (190) set out to determine whether an enzyme preparation would be able to promote the same transformation. By incubation of dregamine hydrochloride with a suspension of liver microsomes from a rat pretreated with phenobarbital (as a good inducer of P-450 cytochromes) in the presence of NADPH and 02, 20-epiervatamine (45) was formed together with the major metabolite Nl -demethyldregamine. It is well known that microsomal reaction on tertiary amines results in Af-oxide formation or N-deal-kylation. Thus it is likely that 45 was derived either from a rearrangement of dregamine JV4-oxide, catalyzed by the iron cytochrome P-450 or from one-electron oxidation of 30. [Pg.81]

Closure of the triazole ring can be achieved either by oxidative formation of the N-N bond, or condensation of an fV-aminopyridone. The latter was formed by iV-amination of pyridines with mesitylhydroxylamine (MSH), or by forming the pyridine ring, starting from cyanoacetic hydrazide with malononitrile or 2-cyanoacrylates. [Pg.617]

Asphalt chemicals, ethyleneamines application, 8 500t, 506 Asphalt emulsifier amine oxides, 2 473 fatty acid amides, 2 458 Asphalt emulsions, 10 131 Asphaltenes, in petroleum vacuum residua, 18 589-590 Asphyxiants, 21 836 Aspirating aerators, 26 165-169 compressed, 26 168-169 propeller driven, 26 168 submersible, 26 169, 170t subsurface, 26 168 Aspiratory, 11 236-237 Aspirin, 4 103-104, 104t, 701 22 17-21. See also Acetylsalicylic acid as trade name, 22 19 for cancer prevention, 2 826 Aspirin resistance, 4 104 ASP oil recovery process, 23 532-533 Assay format, competitive, 14 142 Assay limits, in Investigational New Drug Applications, 18 692 Assays, for silver, 22 650. See also... [Pg.75]

One of the possible ways to stabilize the amine-halonium complexes is to increase the basicity of the amine, bearing in mind that an appropriate one must also not have easily removable P-hydrogens which will lead to oxidation of the amine and formation of an imine. Quinuclidine (pKa of quinuclidinium ion is 11.3 (55)) is 105-106-fold more basic than the pyridines and both the bromonium (10 (36)) and iodonium (11 (57)) BF4 salts have been made and characterized by X-ray crystallography. Interestingly, although the reaction must generally occur as outlined in Figure 7, neither of these ions shows any observable reaction... [Pg.481]

Certain workers3 believed that enhanced activity in the animal body was due to the formation of the amine oxide (IB). [Pg.188]

The primary products obtained from 2-butanol are of mechanistic. significance and may be compared with other eliminations in the sec-butyl system 87). The direction of elimination does not follow the Hofmann rule 88) nor is it governed by statistical factors. The latter would predict 60% 1-butene and 40% 2-butene. The greater amount of 2-alkene and especially the unusual predominance of the cis-olefin over the trans isomer rules out a concerted cis elimination, in which steric factors invariably hinder the formation of cis-olefin. For example, the following ratios oicisjtrans 2-butene are obtained on pyrolysis of 2-butyl compounds acetate, 0.53 89, 90) xanthate, 0.45 (S7) and amine oxide, 0.57 86) whereas dehydration of 2-butanol over the alkali-free alumina (P) gave a cisjtrans ratio of 4.3 (Fig. 3). [Pg.84]

See other pages where Amine oxide formation is mentioned: [Pg.107]    [Pg.51]    [Pg.124]    [Pg.116]    [Pg.284]    [Pg.175]    [Pg.583]    [Pg.356]    [Pg.107]    [Pg.51]    [Pg.124]    [Pg.116]    [Pg.284]    [Pg.175]    [Pg.583]    [Pg.356]    [Pg.311]    [Pg.47]    [Pg.55]    [Pg.228]    [Pg.219]    [Pg.114]    [Pg.135]    [Pg.246]    [Pg.599]    [Pg.135]    [Pg.163]    [Pg.181]    [Pg.97]    [Pg.1189]    [Pg.60]    [Pg.129]    [Pg.137]    [Pg.137]    [Pg.526]    [Pg.527]   
See also in sourсe #XX -- [ Pg.1200 ]



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