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Electrophilic aromatic substitution reactions products

If the Lewis base ( Y ) had acted as a nucleophile and bonded to carbon the prod uct would have been a nonaromatic cyclohexadiene derivative Addition and substitution products arise by alternative reaction paths of a cyclohexadienyl cation Substitution occurs preferentially because there is a substantial driving force favoring rearomatization Figure 12 1 is a potential energy diagram describing the general mechanism of electrophilic aromatic substitution For electrophilic aromatic substitution reactions to... [Pg.476]

Because the carbon atom attached to the ring is positively polarized a carbonyl group behaves m much the same way as a trifluoromethyl group and destabilizes all the cyclo hexadienyl cation intermediates m electrophilic aromatic substitution reactions Attack at any nng position m benzaldehyde is slower than attack m benzene The intermediates for ortho and para substitution are particularly unstable because each has a resonance structure m which there is a positive charge on the carbon that bears the electron withdrawing substituent The intermediate for meta substitution avoids this unfavorable juxtaposition of positive charges is not as unstable and gives rise to most of the product... [Pg.498]

Many of the common electrophilic aromatic substitution reactions can be conducted on indole. CompHcations normally arise either because of excessive reactivity or the relative instabiUty of the substitution product. This is the case with halogenation. [Pg.84]

Isotope effects are also useful in providing insight into other aspects of the mechanisms of individual electrophilic aromatic substitution reactions. In particular, because primary isotope effects are expected only when the breakdown of the c-complex to product is rate-determining, the observation of a substantial points to a rate-... [Pg.566]

A more practical solution to this problem was reported by Larson, in which the amide substrate 20 was treated with oxalyl chloride to afford a 2-chlorooxazolidine-4,5-dione 23. Reaction of this substrate with FeCL affords a reactive A-acyl iminium ion intermediate 24, which undergoes an intramolecular electrophilic aromatic substitution reaction to provide 25. Deprotection of 25 with acidic methanol affords the desired dihydroisoquinoline products 22. This strategy avoids the problematic nitrilium ion intermediate, and provides generally good yields of 3-aryl dihydroisoquinolines. [Pg.379]

With a substituted aromatic ring compound 2, mixtures of isomeric coupling products may be formed the ort/zo-product usually predominates. The rules for regiochemical preferences as known from electrophilic aromatic substitution reactions (see for example Friedel-Crafts acylation), do not apply here. [Pg.141]

Predicting the Product of an Electrophilic Aromatic Substitution Reaction... [Pg.563]

Unlike benzene, pyridine undergoes electrophilic aromatic substitution reactions with great difficulty. Halogenation can be carried out under drastic conditions, but nitration occurs in very low yield, and Friedel-Crafts reactions are not successful. Reactions usually give the 3-substituted product. [Pg.949]

No electrophilic aromatic substitution reactions of toluene, ethylbenzene, and cumene occur with BBrj in the dark the electrophile is too weak for these reactions. The photochemical reactions followed by hydrolysis give the p-isomers of the corresponding boronic acids as the major products (delocalization band in Scheme 9) [44]. [Pg.34]

The first product is derived from a normal electrophilic aromatic substitution reaction of the kind described in the text. The second product is derived from ipso electrophilic aromatic substitution. The mechanism is exactly the same, but in the last step z-Pr+ is lost instead of H+. [Pg.55]

Friedel-Crafts type reactions of strongly deactivated arenes have been the subject of several recent studies indicating involvement of superelectrophilic intermediates. Numerous electrophilic aromatic substitution reactions only work with activated or electron-rich arenes, such as phenols, alkylated arenes, or aryl ethers.5 Since these reactions involve weak electrophiles, aromatic compounds such as benzene, chlorobenzene, or nitrobenzene, either do not react, or give only low yields of products. For example, electrophilic alkylthioalkylation generally works well only with phenolic substrates.6 This can be understood by considering the resonance stabilization of the involved thioalkylcarbenium ion and the delocalization of the electrophilic center (eq 4). With the use of excess Fewis acid, however, the electrophilic reactivity of the alkylthiocarbenium ion can be... [Pg.19]

The large effects of naturally occurring cyclodextrins and their derivatives, which act as miniature reaction vessels, on the ratios of products from some electrophilic aromatic substitution reactions have been restated.6... [Pg.167]

Given the reactants, write the structures of the main organic products of the common electrophilic aromatic substitution reactions (halogenation, nitration, sulfonation, alkylation, and acylation). [Pg.63]

Given two successive electrophilic aromatic substitution reactions, write the structure of the product, with substituents in the correct locations on the ring. [Pg.63]

Predict the product of electrophilic aromatic substitution reactions of pyridine and quinoline. [Pg.251]

Predict the product expected from electrophilic aromatic substitution reactions of pyrrole, furan, and thiophene. [Pg.252]

Regioselectivity in the formation of regioisomers is also observed in electrophilic aromatic substitution reactions. In the case of monosubstituted benzene derivatives, there are three possible regiosomeric products that form at different rates, based on the mechanism of the reaction (see Figure 13). see also Berzelius, Jons Jakob Chirality Dalton, John Davy, Humphry Molecular Structure Scheele, Carl Wohler, Friedrich. [Pg.261]

Explain why these compounds react faster than benzene in electrophilic aromatic substitution reactions and give predominantly ortho and para products ... [Pg.677]

The situation is more complicated if there is more than one substituent on the benzene ring. However, it is usually possible to predict the major products that are formed in an electrophilic aromatic substitution reaction. When the substituents direct to the same position, the prediction is straightforward. For example, consider the case of 2-nitrotoluene. The methyl group directs to the positions ortho and para to itself—that is, to positions 4 and 6. The nitro group directs to positions meta to itself—that is, also to positions 4 and 6. When the reaction is run, the products are found to be almost entirely 2,4-dinitrotoluene and 2,6-dinitrotoluene, as expected ... [Pg.682]

Click Coached Tutorial Problems for additional practice showing the products of Electrophilic Aromatic Substitution Reactions. [Pg.699]

Nitrosobenzene reacts slightly slower than benzene in an electrophilic aromatic substitution reaction and gives predominantly ortho and para products. Explain this behavior. [Pg.733]

Diazonium Salts as Electrophiles Diazo Coupling Arenediazonium ions act as weak electrophiles in electrophilic aromatic substitutions. The products have the structure Ar—N=N—Ar, containing the —N=N— azo linkage. For this reason, the products are called azo compounds, and the reaction is called diazo coupling. Because they are weak electrophiles, diazonium salts react only with strongly activated rings (such as derivatives of aniline and phenol). [Pg.914]

We talked a lot about regioselectivity two chapters ago, when you learned how to predict and explain which product(s) you get from electrophilic aromatic substitution reactions. The functional group is the aromatic ring where it reacts is the reaction s regioselectivity. Going back further, one of the first examples of regioselectivity you came across was nucleophilic addition to an unsaturated ketone. Addition can take place in a 1,2- or a 1,4-fashion—the question of which happens (where the unsaturated ketone reacts) is a question of regioselectivity, which we discussed in Chapters 10 and 23. We shall leave all discussion of stereoselectivity until Chapters 31-34. [Pg.615]

TriCTAs and TeCTAs were prepared by stepwise addition of sulfuryl chloride over 4 h at 60°C. The degree of chlorination was found to be three to four (only tri- and tetrachlorinated thianthrenes were observed as reaction products) when all of the parent compound was consumed. One TriCTA and one TeCTA were obtained as main products. In addition, two other TriCTAs, four TeCTAs, and some PeCTAs were observed in minor concentrations. Because of the ortho- and para-directing properties of sulfur in electrophilic aromatic substitution reactions, 237-TriCTA and 2378-TeCTA, the thio analogue of 2378-TeCDD, were obtained as the main products. Mass spectrometry and H NMR were used in the structure verification. [Pg.295]


See other pages where Electrophilic aromatic substitution reactions products is mentioned: [Pg.498]    [Pg.381]    [Pg.939]    [Pg.156]    [Pg.163]    [Pg.206]    [Pg.227]    [Pg.25]    [Pg.143]    [Pg.733]    [Pg.49]    [Pg.433]    [Pg.505]    [Pg.113]    [Pg.219]    [Pg.691]    [Pg.531]    [Pg.120]    [Pg.28]    [Pg.129]    [Pg.49]    [Pg.3582]   
See also in sourсe #XX -- [ Pg.4 ]




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Aromatic products

Aromatic products production

Aromaticity electrophilic aromatic substitution

Aromatics electrophilic substitution

Aromatics production

Electrophile Electrophilic aromatic substitution

Electrophile reactions Electrophilic aromatic

Electrophilic aromatic reactions

Electrophilic substitution reaction

Product aromatization

Substitutable products

Substitute products

Substitution electrophilic aromatic

Substitution electrophilic aromatic substitutions

Substitution product

Substitution production

Substitution reactions aromatic

Substitution reactions electrophile

Substitution reactions electrophilic aromatic

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