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Free radicals aryl, reactions

As all free-radical arylation reactions, the ptGBH reaction produces a mixture of all three isomers if the arene is unsymmetrical [61,76,79]. The isomer distribution can be seen from the following examples of monosubstituted benzene arylation. Table 3. A number of instances have shown that isomer distribution is indifferent to the catalyst used, this strongly suggests that an aryl radical as an actual arylating agent is formed under either phase transfer or classical GBH conditions. [Pg.22]

In the intermediate complexe of free radical arylation, it is necessary to oxidize the reaction intermediate to avoid dimerization and disporportio-nation (190-193, 346) In this case isomer yield and reactivity will be highest with radical sources producing very oxidative radicals or in solvents playing the role of oxidants in the reaction. The results are summarized in Tables III-29 and III-30. [Pg.366]

Beyer synthesis, 2, 474 electrolytic oxidation, 2, 325 7r-electron density calculations, 2, 316 1-electron reduction, 2, 282, 283 electrophilic halogenation, 2, 49 electrophilic substitution, 2, 49 Emmert reaction, 2, 276 food preservative, 1,411 free radical acylation, 2, 298 free radical alkylation, 2, 45, 295 free radical amidation, 2, 299 free radical arylation, 2, 295 Friedel-Crafts reactions, 2, 208 Friedlander synthesis, 2, 70, 443 fluorination, 2, 199 halogenation, 2, 40 hydrogenation, 2, 45, 284-285, 327 hydrogen-deuterium exchange, 2, 196, 286 hydroxylation, 2, 325 iodination, 2, 202, 320 ionization constants, 2, 172 IR spectra, 2, 18 lithiation, 2, 267... [Pg.831]

Packer and Richardson (1975) and Packer et al. (1980) made use of the fact that electrons can be generated in water by y-radiation from a 60Co source (Scheme 8-29) to induce a free radical chain reaction between diazonium ions and alcohols, aldehydes, or formate ion. It has to be emphasized that the radiolytically formed solvated electron in Scheme 8-29 is only a part of the initiation steps (Scheme 8-30) by which an aryl radical is formed. The aryl radical initiates the propagation steps shown in Scheme 8-31. Here the alcohol, aldehyde, or formate ion (RH2) is the reducing agent (i.e., the electron donor) for the main reaction. The process is a hydro-de-diazoniation. [Pg.190]

Another free-radical arylation method consists of the photolysis of aryl iodides in an aromatic solvent. Yields are generally higher than in 14-17 or 14-21. The aryl iodide may contain OH or COOH groups. The mechanism is similar to that of 14-17. The aryl radicals are generated by the photolytic cleavage ArI AR + T. The reaction has been applied to intramolecular arylation (analogous to the Pschorr reaction). A similar reaction is photolysis of an arylthallium bis(trifluoroacetate) (12-21) in an aromatic solvent. Here too, an unsymmetrical biaryl is produced in good yields. ... [Pg.933]

The relative ease with which aryl benzyl sulfoxides undergo homolytic dissociation (Rayner et al., 1966) as compared to aryl benzyl sulfides or sulfones is supportive of this idea that ArSO radicals are easier to form than ArS or ArS02 radicals. Another interesting set of observations is the following. Booms and Cram (1972) found that optically active arene-sulfinamides ArS(0)NRPh (R = H or CH3) racemize thermally very readily at room temperature and that this racemization is the result of a free radical chain reaction (160) that is initiated by the dissociation of some of the sulfinamide into an ArSO and a PhNR radical (159). While the length of the inhibition... [Pg.131]

Free-radical cyclization reactions nicely complement the Pd(0)-catalyzed intramolecular Heck reaction, which also provides cyclic products from unsaturated halides. Free radicals can be generated easily at saturated carbons from saturated alkyl bromides, and the products are reduced relative to the reactants. In contrast, intramolecular Heck reactions work best for vinyl and aryl bromides (in fact they do not work for alkyl halides), and the products are at the same oxidation level as the reactants. Moreover, free radicals attack the double bond at the internal position, whereas palladium insertion causes cyclization to occur at the external carbon. [Pg.288]

The free-radical arylation of pyridine N-oxides has not been studied systematically, alkylation not at all. When pyridine A-oxide was treated with benzene- and p-chlorobenzenediazonium salts only the 2-arylpyridine jV-oxides were isolated.393 No mention was made of the formation of the 3- and 4-aryl derivatives expected to be produced as well. The phenylation of pyridine N-oxide (diazoaminobenzene at 131° or 181° was found to be the most convenient source of phenyl radicals) was reinvestigated,394 and the reactivities of the nuclear positions found to be in the order 2 > 4 > 3, which is also that predicted6 on the basis of atom localization energy calculations. 2-Phenyl-pyridine N-oxide formed 71-81% of the total phenylation products, whereas the 3-isomer comprised only 5.6-9.6% of that total. The phenylpyridines were found among the by-products of the reaction. [Pg.328]

The free radical arylation of thiazole (391) has been performed either by the Gomberg-Bachmann (392) decomposition of aryldiazonium chlorides (119,393), by the thermal decomposition of benzoyl peroxide (394-397) or N-nitrosoacetanilide (398), or by the photolysis of benzoyl peroxide or iodobenzene (398). The three monophenylthiazoles are obtained in the practically constant proportions 2-phenyl, 60% 5-phenyl, 30% 4-phenyl, 10%, giving the order, 2>5>4, of decreasing reactivity of the three positions of thiazole toward phenyl radicals (398). Competition reactions with nitrobenzene (397) gave an estimation of the globed reactivity of thiazole relative to benzene of 0.75 with the partial rate factors f2 = 2.2, /s=1.9, /4 = 0.5. When the thermolysis of benzoyl peroxide is performed in acetic acid solution, the substrate in reaction is the conjugate acid of thiazole the global reactivity is enhanced to 1.25,... [Pg.62]

The substitution of aluminum by oxygen can be effected by various peroxide derivatives, such as di-r-butyl peroxide, benzoyl peroxide and r-butyl perbenzoate. The main reaction is accompanied by telltale free-radical side reactions, such as the formation of RR from R3AI, which become major pathways with aryl and vinyl compounds. Oxidation of alkenyl derivative (56) with r-butyl perbenzoate yields 45% of a mixture of cis and trans ethers (57 equation 44). As of yet there is no generally applicable, highly efficient method for oxidizing vinylaluminum compounds. [Pg.753]

Although the S-H bond adds readily to alkynes in a free radical chain reaction, the relative ease of addition of S-H to alkenes under the same conditions makes the reaction difficult to stop at the single addition stage. Most commonly a mixture of thiaalkenes and dithiaalkanes is obtained and, in the latter, the sulfurs are on vicinal carbon atoms. Aryl thiolates usually give geminal dithia products. Some typical examples of free radical alkyne RSH insertions are given in Table... [Pg.570]

Walling and Rabinowitz observed (299,300) that, in the presence of appropriate initiators, trialkyl phosphites can undergo a free radical chain reaction with alkyl disulfides to yield an 0,0,0-trialkyl phosphorothioate and an alkyl sulfide (eq. 11a). Because of the strength of the aryl-sulfur bond in phenyl disulfide, an ethyl rather than an aryl radical would be eliminated from the radical intermediate (eq. 11b) in this instance. [Pg.82]

The types of compounds that can be polymerized readily by the radical-chain mechanism are the same types that easily undergo free-radical addition reactions. Alkenes with aryl, ester, nitrile, or halide substituent groups that can stabilize the intermediate radical are most susceptible to radical polymerization. Terminal alkenes are generally more reactive toward radical-chain polymerization than more highly substituted isomers. The dominant mode of addition in radical-chain polymerization is head-to-tail. The reason for this orientation is that each successive addition of monomer takes place in such a way that the most stable possible radical intermediate is formed. For example, the addition to styrene occurs to give the phenyl-substituted radical to acrylonitrile, to give the cyano-substituted radical ... [Pg.461]

The thermal decomposition reaction of a diaroylperoxide, (ArCOO)2, in a liquid arene, Ar, furnishes a biaryl, Ar-Ar [101-107]. At elevated temperatures the diaroyl peroxide dissociates by the homolytic pathway to generate the arylcarboxy-radicals, ArCOO, which are prone to rapid decarboxylation forming the aryl radicals, Ar. The latter react with the arene, e.g. benzene, by the free-radical arylation mechanism, closely similar to the classical Gomberg-Bachmann-Hey reaction pathway, to give the biaryls, Ar-Ar, in moderate to good yields [101-103], Scheme 28. [Pg.29]

The oxidative coupling reactions of certain electron-rich arenes under suitable reaction conditions proceed, at least partially, via free-radical mechanism. Scheme 3. The phenolate anion is oxidized by suitable one-electron oxidant to the phenoxyl-radical whose tautomeric form is aryl-radical on the adjacent carbon atom. The symmetrical biaryl is formed by coupling of the latter, whereas the unsymmetrical one is produced by free-radical arylation of the second arene molecule, usually in an intramolecular... [Pg.210]

The reactions are performed by slow addition (10-15 h) of benzene solution of tri-K-butyltin hydride (1.3 eq.) and AIBN (0.7 eq.) to the boiling benzene solution of the corresponding Motherwell s precursor. Tri- -butyltin hydride in the presence of radical initiator such as AIBN is well known reagent for the generation of aryl radicals from aryl iodides and bromides [5]. Side-reactions in this approach are the formation of direct free-radical addition and dehalogenation products. The formation of the latter side-product is minimized by slow addition of tin hydride. However, the formation of direct free-radical addition, the Pschorr-type product is a serious side-reaction. For example, compound 423 at 75% conversion gives 34% of biaryl 424 as zp o-product (Motherwell reaction pathway), and 39% of biaryl 425, as the product of direct free-radical arylation, analogously to the Pschorr reaction pathway [1], Scheme 2. [Pg.242]

Methodology similar to Pschorr and Motherwell reactions, was employed in the synthesis of phenanthrene-type structures, where an intramolecular free-radical arylation was accomplished by the reaction of bromo-c/s-stilbene 428 with tri-n-butyl tin hydride, giving 429 in 85% yield [6], respectively. Scheme 4. [Pg.243]

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See also in sourсe #XX -- [ Pg.662 ]



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Free radical arylation

Free radical reaction

Radicals free-radical reactions

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