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Rearrangement, aryl carboxylate

The rearrangement occurs more readily when activating groups (aryl, carboxyl, etc.) are attached to the triple bond. Jacobs [38] reports that a reaction involving adsorption of an acetylenic compound on an active basic surface has led to the practical synthesis of arylallenes, allenyl ethers, allenyl halides, and other substituted allenes. [Pg.15]

Advantageously, catalytic amounts of rare earth metal triflates are used instead of stoichiometric amounts of aluminum trichloride in catalytic Fries rearrangements of carboxylic acid aryl esters furnishing keto building blocks, e.g. 10... [Pg.105]

One limitation is that this re=action cannot be used for rearrangement of amides of aryl carboxylic acids because anilines are subject to further oxidation. ... [Pg.32]

However, with 1 equivalent of benzoic acid at room temperature, a slow cyclization to the 1,3,5-oxadiazine-2,4(3//)-dione (125 R = Ph) takes place via a Chapman rearrangement (123)(124) of the 6-benzoyloxy-l,3,5-oxadiazine-2,4(3//)-dione (123 R = Ph) as outlined in Scheme 13 <86CB669>. Other aryl carboxylic acids yield only complex mixtures, whereas with alkyl carboxylic acids and with trichloroacetic acid, l,3,5-oxadiazine-2,4(3//)-diones (125 R = alkyl and H, respectively) are... [Pg.802]

By application of the Schmidt reaction, the conversion of a carboxylic acid into an amine that has one carbon atom less than the carboxylic acid, can be achieved in one step. This may be of advantage when compared to the Curtius reaction or the Hofmann rearrangement, however the reaction conditions are more drastic. With long-chain, aliphatic carboxylic acids yields are generally good, while with aryl derivatives yields are often low. [Pg.253]

The Rh2(DOSP)4 catalysts (6b) of Davies have proven to be remarkably effective for highly enantioselective cydopropanation reactions of aryl- and vinyl-diazoacetates [2]. The discovery that enantiocontrol could be enhanced when reactions were performed in pentane [35] added advantages that could be attributed to the solvent-directed orientation of chiral attachments of the ligand carboxylates [59]. In addition to the synthesis of (+)-sertraline (1) [6], the uses of this methodology have been extended to the construction of cyclopropane amino acids (Eq. 3) [35], the synthesis of tricyclic systems such as 22 (Eq. 4) [60], and, as an example of tandem cyclopropanation-Cope rearrangement, an efficient asymmetric synthesis of epi-tremulane 23 (Eq. 5) [61]. [Pg.211]

The furoxan ring is notably resistant to electrophilic attack and reaction normally takes place at the substituents. Thus aryl groups attached to monocyclic furoxans and the homocyclic ring of benzofuroxans are nitrated and halogenated without disruption of the heterocycle. Reaction with acid is also slow protonation is predicted to occur at N-5 <89KGS1261> and benzofuroxans have pKj, values of ca. 8, similar to those of benzofurazans. Monosubstituted furoxans are, as expected, less stable and can be hydrolyzed to the corresponding carboxylic acid. Treatment of the parent furoxan (3) with concentrated sulfuric acid results in rearrangement to (hydroxyimino)acetonitrile oxide (HON=CHC=N —O ) and subsequent dimerization to bis(hydroxyiminomethyl)furoxan... [Pg.241]

Acyl substituents at the 3- and/or 4-positions result in decreased hydrolytic stability compared with the alkyl and aryl derivatives described above. Despite this constraint most of the usual reactions of the carbonyl group are possible. Aldehydes <9ILA1211> and ketones are oxidized to the carboxylic acid, borohydride reduction affords the expected alcohols, and epoxides are formed on reaction with diazomethane. Oximes and arylhydrazones are formed with hydroxylamine and arylhydrazines, and the products may subsequently undergo monocyclic rearrangement involving the oxadiazole to give the corresponding isomeric furazans and 1,2,3-triazoles (Section 4.05.5.1.4). [Pg.247]

Ring-closure techniques are more commonly used to obtain 3-alkylbenzo[6]thiophenes. Thus, acid-catalyzed cyclization of arylthio methyl ketones gives the 3-alkylbenzo[6]thio-phenes in good yield, with little rearrangement (equation 3). Formation of the 3-aryl-benzo[6]thiophenes by this approach is complicated, however, by rearrangement to the 2-isomer (Section 3.15.2.3.2). 3-Methylbenzo[f> Jthiophene is also obtained by decarboxylation of the corresponding 2-carboxylic acid (equation 4), readily available from ar-mer-captocinnamic acids (Section 3.15.2.1.1). [Pg.915]


See other pages where Rearrangement, aryl carboxylate is mentioned: [Pg.169]    [Pg.114]    [Pg.309]    [Pg.79]    [Pg.699]    [Pg.702]    [Pg.712]    [Pg.1417]    [Pg.172]    [Pg.409]    [Pg.699]    [Pg.233]    [Pg.3]    [Pg.354]    [Pg.168]    [Pg.504]    [Pg.278]    [Pg.225]    [Pg.57]    [Pg.415]    [Pg.132]    [Pg.141]    [Pg.333]    [Pg.459]    [Pg.540]    [Pg.1098]    [Pg.237]    [Pg.920]    [Pg.114]    [Pg.309]    [Pg.117]    [Pg.375]    [Pg.487]    [Pg.553]   


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2-aryl 4-carboxylates

Aryl carboxylate

Aryl rearrangements

Carboxylate ions, aryl rearrangements

Rearrangement, aryl carboxylate group

Rearrangement, aryl carboxylate isolation

Rearrangement, aryl carboxylate nucleophilic

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