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Alkylation furan

Furan, 2-alkenyl-3-hydroxytetrahydro-synthesis, 4, 677 Furan, alkyl-reactions, 4, 644 synthesis, 4, 710 Furan, 2-alkyl-mass spectra, 4, 21-22 synthesis, 4, 666 Furan, 3-alkyl-mass spectra, 4, 21-22 synthesis, 4, 665, 710 Furan, 5-alkyl-2-phenylthio-reactions, 4, 80 Furan, 2-alkyltetrahydro-synthesis, 4, 675, 711 Furan, 3-amido-synthesis, 4, 665 Furan, 2-amino-synthesis, 4, 74, 121, 661 tautomerism, 4, 38 Furan, 3-amino-tautomerism, 4, 38 Furan, 2-amino-3-cyano-synthesis, 4, 661, 689, 712 Furan, 3-amino-2-methyl-reaction, 4, 74 Furan, 2-aryl-reactions... [Pg.629]

Scheme 1) whereas the reaction with the D-man/io-hexodialdo-l,5-pyranose derivative 3 produced, in low yield, the cyanohydrin 4 having an L-glycero-D-manno configuration and the stereoisomeric epimer at C-5, rather than at C-6 [14J. With an atm toward the synthesis of d- and L-glycero-D-manno-heptoses, the reaction of 3 with other reagents (2-inethyl-furan, alkyl magnesium chlorides) was also explored, without any substantial improvement of either stereoselectivity or yield. [Pg.175]

Benzofuran-3(2/f)-ones (396) exist in the keto form but undergo ready enolization. Acetylation with acetic anhydride and sodium acetate affords 3-acetoxybenzo[6]furans, but reaction under acidic conditions usually supplies these products admixed with 3-acetoxy-2-acetylbenzo[6]furans. Alkylation usually furnishes a mixture of O- and C-alkylated products. 3-Acetoxy-6-methoxy-4-methylbenzo[6]furan, on Vilsmeier reaction, supplies the 3-chlorobenzo[6]furan-2-carbaldehyde, the product expected from an enolizable ketone (72AJC545). Benzofuran-3(2//)-ones react normally with carbonyl reagents. Grignard reagents react in the expected way and dehydration of the intermediate affords a 3-substituted benzo[6]furan. The methylene group is reactive so that self condensation, condensation with aldehydes and ketones and reaction with Michael acceptors all occur readily. [Pg.650]

A one-step furan alkylation/eliminative cyclization between IV-tosylfurfurylamine and electron-rich o-(3-hydroxypropyl)anilines under refluxing conditions in strong acids provided indole derivatives in m est yield, as depicted in the example below <05TL8443>. [Pg.191]

So far only one example of furan alkylation assisted by arene complexes has been reported. D.J. Milner has shown that furan reacts with tert-hutyl chloride in the presence of (TX -mesitylene)Mo(CO)3 to afford a mixture of 2-fert-butyl-furan and 2,5-di-tert-butylfuran in 65-80% yields [20]. Both mono- and disub-stituted furans can be prepared as the major product by changing the furan/t-BuCl ratio. Although there is only one report of this reaction, the ability to synthesize mono- and disubstituted furans in a simple manner reflects the potential of this methodology which can be used for preparing substituted furans, that are valuable synthetic materials. [Pg.187]

Fischer indole synthesis, 91-95 Formamidine disulfide, salts of, 281, 282 Formazans, oxidation of, 37 Furans, alkyl-, ring-opening of, 63... [Pg.213]

The mass spectrum of 2-pyrone shows an abundant molecular ion and a very prominent ion due to loss of CO and formation of the furan radical cation. Loss of CO from 4-pyrone, on the other hand, is almost negligible, and the retro-Diels-Alder fragmentation pathway dominates. In alkyl-substituted 2-pyrones loss of CO is followed by loss of a hydrogen atom from the alkyl substituent and ring expansion of the resultant cation to the very stable pyrylium cation. Similar trends are observed with the benzo analogues of the pyrones, although in some cases both modes of fragmentation are observed. Thus, coumarins. [Pg.22]

Examples of the remaining potential 3,4-dihydroxy heterocycles are presently restricted to furan and thiophene. Although the parent 3,4-dihydroxyfuran apparently exists as the dioxo tautomer (86), derivatives bearing 2-alkyl or 2,5-dialkyl substituents prefer the keto-enol structure (87) (71T3839, 73HCA1882). The thiophene analogues also prefer the tautomeric structure (87), except in the case of the 2,5-diethoxycarbonyl derivative which has the fully aromatic structure (88) (71T3839). [Pg.37]

Mercapto derivatives of furan, thiophene, selenophene (77ACS(B)198) and pyrrole (72AJC985) all exist predominantly in the thiol form. 2-Mercaptobenzothiophene is also a thiol (70JCS(C)243i) whereas 2-mercaptoindole is mainly indoline-2-thione (89) (69CPB550). The finely balanced nature of this system is indicated by the fact that a 3-aryl, but not a 3-alkyl, substituent will stabilize the 2-thiol form, whereas for 3-aryl-fV-methyl derivatives the 2-thione tautomer is preferred (71CC836). [Pg.38]

A comparison of the relative basicities of pyrrole, furan and thiophene may be made by comparing the pK values of their 2,5-di-t-butyl derivatives, which were found to be -1.01, —10.01 and —10.16, respectively. In each case protonation was shown by NMR to occur at position 2. The base-strengthening effect of alkyl substitution is clearly apparent by comparison of pyrrole and its alkyl derivatives, e.g. A-methylpyrrole has a pKa. for a-protonation of -2.9 and 2,3,4,5-tetramethylpyrrole has a pK of 4-3.7. In general, protonation of a-alkylpyrroles occurs at the a -position whereas /3-alkylpyrroles are protonated at the adjacent a-position. As expected, electron-withdrawing groups are base-weakening thus A-phenylpyrrole is reported to have a p/sTa of -5.8. The IR spectrum of the hydrochloride of 2-formylpyrrole indicates that protonation occurs mainly at the carbonyl oxygen atom and only to a limited extent at C-5. [Pg.47]

Alkylation of furan and thiophene has been effected with alkenes and catalysts such as phosphoric acid and boron trifluoride. In general, Friedel-Crafts alkylation of furans or thiophenes is not preparatively useful, partly because of polymerization by the catalyst and partly because of polyalkylation. [Pg.53]

Pyrroles, furans and thiophenes undergo photoinduced alkylation with diarylalkenes provided that the alkene and the heteroaromatic compound have similar oxidation potentials, indicating that alkylation can occur by a non-ionic mechanism (Scheme 20) (81JA5570). [Pg.53]

It is estimated that thiophene reacts with phenyl radicals approximately three times as fast as benzene. Intramolecular radical attack on furan and thiophene rings occurs when oxime derivatives of type (112) are treated with persulfate (8UCS(Pt)984). It has been found that intramolecular homolytic alkylation occurs with equal facility at the 2- and 3-positions of the thiophene nucleus whereas intermolecular homolytic substitution occurs mainly at position 2. [Pg.62]

The dianions derived from furan- and thiophene-carboxylic acids by deprotonation with LDA have been reacted with various electrophiles (Scheme 64). The oxygen dianions reacted efficiently with aldehydes and ketones but not so efficiently with alkyl halides or epoxides. The sulfur dianions reacted with allyl bromide, a reaction which failed in the case of the dianions derived from furancarboxylic acids, and are therefore judged to be the softer nucleophiles (81JCS(Pl)1125,80TL505l). [Pg.72]

Acyl-pyrroles, -furans and -thiophenes in general have a similar pattern of reactivity to benzenoid ketones. Acyl groups in 2,5-disubstituted derivatives are sometimes displaced during the course of electrophilic substitution reactions. iV-Alkyl-2-acylpyrroles are converted by strong anhydrous acid to A-alkyl-3-acylpyrroles. Similar treatment of N-unsubstituted 2- or 3-acyIpyrroles yields an equilibrium mixture of 2- and 3-acylpyrroles pyrrolecarbaldehydes also afford isomeric mixtures 81JOC839). The probable mechanism of these rearrangements is shown in Scheme 65. A similar mechanism has been proposed for the isomerization of acetylindoles. [Pg.73]

Pyrrolethiols, readily obtained from the corresponding thiocyanates by reduction or treatment with alkali, rapidly oxidize to the corresponding disulfides. They are converted into thioethers by reaction with alkyl halides in the presence of base. Both furan- and thiophene-thiols exist predominantly as such rather than in tautomeric thione forms. [Pg.78]

Benzo[b]furan, 2-alkyl-2,3-dihydro-synthesis, 4, 680 Benzo[b]furan, 2-amino-synthesis, 4, 710 Benzo[b]furan, 3-amino-tautomerism, 4, 38 Benzo[b]furan, 2-amino-2,3-dihydro-applications, 4, 708... [Pg.546]

Furan, 3-acetyl-5-(hydroxymethyl)-2-methyl-synthesis, 4, 663 Furan, 2-acyl-synthesis, 4, 148, 690 Furan, 3-acyl-synthesis, 4, 662, 670 Furan, 4-acyl-2-alkyl-synthesis, 4, 688 Furan, 3-acylamino-tautomerism, 4, 38... [Pg.629]

Furan-2-carbonyl chloride, 5-alkyl-3,4-dichloro-synthesis, 4, 690 Furancarboxamides rotational isomerism, 4, 543 Furan-2-carboxylic acid, 5-acetylamino-ethyl ester reactions, 4, 647 Furan-2-carboxylic acid, amino-properties, 4, 708 Furan-2-carboxylic acid, 5-bromo-nitration, 4, 603, 711 Furan-2-carboxylic acid, 3-methyl-methyl ester bromination, 4, 604 Furan-2-carboxylic acid, 5-methyl-nitration, 4, 602... [Pg.632]

Aromatic ethers and furans undergo alkoxylation by addition upon electrolysis in an alcohol containing a suitable electrolyte.Other compounds such as aromatic hydrocarbons, alkenes, A -alkyl amides, and ethers lead to alkoxylated products by substitution. Two mechanisms for these electrochemical alkoxylations are currently discussed. The first one consists of direct oxidation of the substrate to give the radical cation which reacts with the alcohol, followed by reoxidation of the intermediate radical and either alcoholysis or elimination of a proton to the final product. In the second mechanism the primary step is the oxidation of the alcoholate to give an alkoxyl radical which then reacts with the substrate, the consequent steps then being the same as above. The formation of quinone acetals in particular seems to proceed via the second mechanism. ... [Pg.94]

Acetyl benzoyl peroxide Furan Inorganic salts of alkyl nitrates... [Pg.1026]


See other pages where Alkylation furan is mentioned: [Pg.126]    [Pg.425]    [Pg.181]    [Pg.187]    [Pg.166]    [Pg.596]    [Pg.126]    [Pg.425]    [Pg.181]    [Pg.187]    [Pg.166]    [Pg.596]    [Pg.301]    [Pg.319]    [Pg.22]    [Pg.3]    [Pg.21]    [Pg.36]    [Pg.45]    [Pg.46]    [Pg.70]    [Pg.76]    [Pg.546]    [Pg.548]    [Pg.634]    [Pg.733]    [Pg.45]   
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2-Alkyl-substituted benzo furans

Alkyl furans

Alkyl furans

Benzo furans, alkyl

Benzo furans, alkyl synthesis

Furan arene alkylation

Furan asymmetric alkylation

Furan, 2-methyltetrahydroalkylation benzene alkylation

Furan, tetrahydroarene alkylation synthesis

Furans Friedel-Crafts alkylation

Furans alkylation reactions

Furans, alkyl-, ring-opening

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