Biaryls reaction

When subjected to Ullmann biaryl reactions, 8-bromo-l-oxazolinylnaph-thalene (,S)-27 can be converted to the 8,8 -substituted binaphthyl 28 in high diastereomeric excess (another isomer, the (a/ ,b )-diastcrcomer, is less than 3%).40... 

The second step is carried out by adding a 15-40% aqueous solution of sodium hydroxide dropwise to a well-stirred mixture of the cold dia-zonium salt solution and the aromatic liquid until a slight excess of alkali is present. This procedure avoids the isolation of the unstable, explosive diazohydroxides of Bamberger,1 which are formed from the diazonium salt and the alkali. The diazohydroxide is extracted by the aromatic liquid as it is formed. The biaryl reaction takes place in the organic liquid and is complete when evolution of nitrogen ceases. In the example given, 4-bromobiphenyl is obtained in 35-46% yield. 

Azo compounds are formed to some extent in the biaryl reactions. From the reaction between diazotized p-toluidine and benzene, azo-p-toluene, CH3C6H4N=NC6H4CH3, was isolated, indicating that, in this particular instance at least, the azo compound was derived entirely from the diazonium compound. In addition to these types, of compounds, a considerable amount of high-boiling material is usually formed in the reactions. 

Aromatic substitution reactions are typically carried out in high yield using metal-catalyzed cross-coupling reactions (see Chapter 29) [48-50]. In particular, the biaryl reactions are difficult to obtain high yield without a metal catalyst. However, there are some non-metal-catalyzed coupling strategies that can result in high-yield reactions. 

The palladium-catalysed reaction of aryl triflates with arylboronic acids has also been used to produce biaryls. Reaction of the bis(triflate) of 4-methyl-6,7-dihydroxycoumarin results in selective substitution at the 7-position to produce derivatives (133), which can undergo substitution of the second triflate group at higher temperatures. " Site selectivity in the reaction of the methyl naphthoate derivative (134), resulting in substitution of the triflate group, has been attributed to electronic ortho-effects. Further replacement of the bromine substituent may yield diarylated derivatives. The palladium-catalysed... 

The majority of studies in this field have addressed the Suzuki reaction (Eq. 1), which is arguably the most successful and popular cross-coupling methodology to date, thanks to the availabihty and ease of handling of the reactants, to the economical significance of the biaryl reaction products, and to the efficiency exhibited by several catalytic systems, particularly by Pd-containing catalysts ... 

Carbon-oxygen bonds are formed by the Ullmann reaction (- coupling of aryl halides with copper) which has been varied in alkaloid chemistry to produce diaryl ethers instead of biaryls. This is achieved by the use of CuO in basic media (T. Kametani, 1969 R.W. Dos-kotch, 1971). 

Another area of interest to the industrial sector is the development of a more efficient synthesis of biaryl compounds. This has been accompHshed using a Ni(II)-cataly2ed Grignard coupling reaction with an aryl haUde (86—89). 

The enhancement of the electrophilic properties of thaHium(III) ttifluoroacetate makes it a very important thaHation reagent. The products of thaHation, eg, arylthaHium bis(ttifluoracetate), undergo a variety of substitution reactions, yielding iodides, fluorides, nitriles, thiophenols, phenols, and biaryls. 

The closely related N- arylazoaziridine system (278) decomposes in refluxing benzene to give aryl azides and alkenes, again stereospecifically (70T3245). However, biaryls, arenes and other products typical of homolytic processes are also formed in a competing reaction, although this pathway can be suppressed by the use of a polar solvent and electron withdrawing aryl substituents. 

An alternative reaction mechanism has been suggested for nitroarylation of enolates. An impetus for considering other mechanisms is the fact that the by-products which might be expected from aryl radicals, such as reduction products from hydrogen abstraction from the solvent or biaryls from coupling, are not observed. One alternative is that, rather than being a chain process, the reaction may involve recombination whereby the radicals combine more rapidly than they separate. 

Meyers has also reported the use of chiral oxazolines in asymmetric copper-catalyzed Ullmann coupling reactions. For example, treatment of bromooxazoline 50 with activated copper powder in refluxing DMF afforded binaphthyl oxazoline 51 as a 93 7 mixture of atropisomers diastereomerically pure material was obtained in 57% yield after a single recrystallization. Reductive cleavage of the oxazoline groups as described above afforded diol 52 in 88% yield. This methodology has also been applied to the synthesis of biaryl derivatives. 

In 1956 it was found that when pyridine is refluxed with a modified Raney-nickel catalyst, 2,2 -bipyridine (1) is formed in satisfactory yield. The isomeric bipyridines could not be detected, and the product was readily purified. Similar heterocyclic biaryls have been formed in the same way from substituted pyridines and from some related compounds, the yield being dependent on the nature of the compound. The reaction has become the method of choice for the preparation of 2,2 -bipyridine, and it is now used on an industrial scale. Bipyridyls are of particular importance as chelating agents. 

Reaction of -picoline with a nickel-alumina catalyst has been reported to give a mixture of four isomeric dimethylbipyridines, one of which has been identified at 6,6 -dimethyl-2,2 -bipyridine. With palladium-on-carbon, 2,4-lutidine was found to be more reactive than pyridine,and the isolated biaryl has been assigned the structure (2). However, some confusion arises from the statement that this... 

Reaction of -picoline over degassed Raney nickel was found to give 5,5 -dimethyl-2,2 -bipyridine (5), the structure of which was established by its synthesis from 2-bromo-5-methylpyridine. Oxidation of this dimethyl-2,2 -bipyridine, and similar oxidation of the diethyl-2,2 -bipyridine derived from 3-ethylpyridinc, gave the corresponding dicarboxylic acid and the same acid was produced by the action of degassed Raney nickel on sodium nicotinate (in water) or on ethyl nicotinate. These transformations established the 5,5 -substitution pattern for three 2,2 -bipyridines derived from 3-substituted pyridines but such evidence is not available for the biaryls... 

Relatively few pyridines with substituents other than alkyl groups have so far been examined, and with some of these the reaction has been carried out only in the presence of added solvent. A comparison of the reactivities of these pyridines is therefore difficult. It has, however, been established that the presence of benzoyl groups in the 3- and 4-positions causes a very marked drop in the yields of the corresponding 2,2 -bipyridines. The 3- and 4-benzylpyridines were found to be more reactive but even in the absence of solvent, and in vacuo, 4-benzylpyridine gave only about one-third of the yield of the 2,2 -bipyridine compared with pyridine itself. Ethyl nicotinate in the absence of solvent and under vacuum -- gave a similar yield of biaryl but 4-phenylpyridine was found to be less reactive. 

Table II shows that, at least for the reactions with quinoline and with 4-methylquinoline (lepidine), nickel-alumina and degassed Raney nickel catalysts are of similar efficiency but better yields have been obtained with degassed Raney nickel, and only this catalyst produces the biaryl from 7-methyIquinoIine.

Several products other than 2,2 -biaryls have been isolated following reaction of pyridines with metal catalysts. From the reaction of a-picoline with nickel-alumina, Willink and Wibaut isolated three dimethylbipyridines in addition to the 6,6 -dimethyl-2,2 -bipyridine but their structures have not been elucidated. From the reaction of quinaldine with palladium-on-carbon, Rapoport and his co-workers " obtained a by-product which they regarded as l,2-di(2-quinolyl)-ethane. From the reactions of pyridines and quinolines with degassed Raney nickel several different types of by-product have been identified. The structures and modes of formation of these compounds are of interest as they lead to a better insight into the processes occurring when pyridines interact with metal catalysts. 

Traditionally, the synthesis of symmetrical biaryls was routinely accomplished using the Ullmann reaction. Recently, palladium-catalyzed homocoupling of aryl halides has also been demonstrated to rival the utility of the Ullmann coupling. As illustrated in Scheme 21, using Pd(OAc)2 as the... 

Chiral aluminum catalyst 2, prepared from Et2AlCl and a Vaulted biaryl ligand, is reported to be an effective Lewis acid catalyst of the Diels-AIder reaction between methacrolein and cyclopentadiene, affording the adduct in 97.7% ee [4] (Scheme 1.2). Although the Diels-AIder reaction with other a,/ -unsaturated aldehydes has not been described, that only 0.5 mol% loading is sufficient to promote the reaction is a great advantage of this catalyst. 

An idustrative example is die forniation of die symmetric biaryl from die reaction between CuCi-,H4NMe2-2 and ICi-,H4NMe2-2, wbidi has been studied in detad in die audiots laboratory [95]. Wlieti diis reaction is carried oul in benzene as a solvent, die reaction slops wbeti one diitd of die original otganocoppet compound has been consumed iEqn. 1 in Sdienie 1.20). 

Arenediazonium species 1 can be reacted with another aromatic substrate 2, by the Gomberg-Bachmann procedure, to yield biaryl compounds 3. The intramolecular variant is called the Pschorr reaction ... 

The very reactive phenyl radical reacts with the aromatic substrate 2, present in the reaction mixture. Subsequent loss of a hydrogen radical, which then combines with 7 to give 4, yields a biaryl coupling product e.g. the unsymmetrical biphenyl derivative 3 ... 

The Pschorr reaction also works with substrates containing a bridge other than oxygen. Thus various tricyclic products containing a biaryl subunit are accessible, e.g. carbazoles and fluorenes. 

In addition to sodium, other metals have found application for the Wurtz coupling reaction, e.g. zinc, iron, copper, lithium, magnesium. The use of ultrasound can have positive effect on reactivity as well as rate and yield of this two-phase reaction aryl halides can then even undergo an aryl-aryl coupling reaction to yield biaryls. ... 

The pharmacological versatility of this general substitution strategy is further illustrated by diazonium coupling of 14 with 2-nitrobenzenediazonium chloride to produce biarylal-dehyde 18. Formation of the oxime with hydroxylamine is followed by dehydration to the nitrile. Reaction with anhydrous methanolic hydrogen chloride leads to imino ether and addition-elimination of ammonia leads to the antidepressant amid-ine, nitrafudam (20). ... 

Galli (1988, p. 781) does not discuss this problem in his review. However, March (1992, p. 719) emphasizes the complexity of the elementary steps in homolytic reactions forming biaryls (footnote 334). 

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