Benzene, deprotonation

The carbocation can attack benzene. Deprotonation of the product then gives ethylbenzene ... 

Fig. 27 Stoichiometric dependence of benzene deprotonation by magnesiate TMEDA Na(TMP) (nBu)Mg(TMP)...

In some cases acid amide formation was observed on attempted deprotonation at oxaziridine ring carbon. 2-r-Butyl-3-(4 -nitrophenyl)oxaziridine (67) was converted to the anion of acid amide (68) by sodium amide (69TL3887), while 2-(4 -nitrobenzoyl)-3-phenyl-oxaziridine (69) afforded the diacylimide (70) by addition of cyclohexylamine to its benzene solution at room temperature (67CB2593). 

The effect of pH is rarely of use for pK measurement it is more often of use in identifying the site of protonation/deprotonation when several basic or acidic sites are present. Knowing the incremental substitutent effects Z of amino and ammonium groups on benzene ring shifts in aniline and in the anilinium ion (40), one can decide which of the nitrogen atoms is protonated in procaine hydrochloride (problem 24). 

Bromination has been shown not to exhibit a primary kinetic isotope effect in the case of benzene, bromobenzene, toluene, or methoxybenzene. There are several examples of substrates which do show significant isotope effects, including substituted anisoles, JV,iV-dimethylanilines, and 1,3,5-trialkylbenzenes. The observation of isotope effects in highly substituted systems seems to be the result of steric factors that can operate in two ways. There may be resistance to the bromine taking up a position coplanar with adjacent substituents in the aromatization step. This would favor return of the ff-complex to reactants. In addition, the steric bulk of several substituents may hinder solvent or other base from assisting in the proton removal. Either factor would allow deprotonation to become rate-controlling. 

Kyba and eoworkers prepared the similar, but not identical compound, 26, using quite a different approach. In this synthesis, pentaphenylcyclopentaphosphine (22) is converted into benzotriphosphole (23) by reduction with potassium metal in THF, followed by treatment with o "t/20-dichlorobenzene. Lithium aluminum hydride reduction of 23 affords l,2-i>/s(phenylphosphino)benzene, 24. The secondary phosphine may be deprotonated with n-butyllithium and alkylated with 3-chlorobromopropane. The twoarmed bis-phosphine (25) which results may be treated with the dianion of 24 at high dilution to yield macrocycle 26. The overall yield of 26 is about 4%. The synthetic approach is illustrated in Eq. (6.16), below. 

Thus the reactions of cyclic or acyclic enamines with acrylic esters or acrylonitrile can be directed to the exclusive formation of monoalkylated ketones (3,294-301). The corresponding enolate anion alkylations lead preferentially to di- or higher-alkylation products. However, by proper choice of reaction conditions, enamines can also be used for the preferential formation of higher alkylation products, if these are desired. Such reactions are valuable in the a substitution of aldehydes, which undergo self-condensation in base-catalyzed reactions (117,118). Monoalkylation products are favored in nonhydroxylic solvents such as benzene or dioxane, whereas dialkylation products can be obtained in hydroxylic solvents such as methanol. The difference in products can be ascribed to the differing fates of an initially formed zwitterionic intermediate. Collapse to a cyclobutane takes place in a nonprotonic solvent, whereas protonation on the newly introduced substitutent and deprotonation of the imonium salt, in alcohol, leads to a new enamine available for further substitution. 

Besides simple alkyl-substituted sulfoxides, (a-chloroalkyl)sulfoxides have been used as reagents for diastereoselective addition reactions. Thus, a synthesis of enantiomerically pure 2-hydroxy carboxylates is based on the addition of (-)-l-[(l-chlorobutyl)sulfinyl]-4-methyl-benzene (10) to aldehydes433. The sulfoxide, optically pure with respect to the sulfoxide chirality but a mixture of diastereomers with respect to the a-sulfinyl carbon, can be readily deprotonated at — 55 °C. Subsequent addition to aldehydes afforded a mixture of the diastereomers 11A and 11B. Although the diastereoselectivity of the addition reaction is very low, the diastereomers are easily separated by flash chromatography. Thermal elimination of the sulfinyl group in refluxing xylene cleanly afforded the vinyl chlorides 12 A/12B in high chemical yield as a mixture of E- and Z-isomers. After ozonolysis in ethanol, followed by reductive workup, enantiomerically pure ethyl a-hydroxycarboxylates were obtained. 

In a synthesis of 2,3-di(hetero)arylpyrido[3,2 [l,4]thiazepines developed by Couture, 2-chloro-3-formylpyridine is reacted with arylmethylamines to form the imines. Deprotonation with LDA at -78 °C followed by treatment with non enolisable aryl thioesters gives the title compounds which may be further annulated by irradiation in benzene in the presence of iodine and propylene oxide <96S986> (Scheme 14). 

Cl—Al Cly) intermediate or a carbocation C AICI4 This intermediate electrophilically attacks the benzene ring to generate a benzenonium ion intermediate which gives alkylated benzene through deprotonation by aluminum tetrachloride anion. Finally the hydrogen aluminum tetrachloride complex affords aluminum chloride and hydrogen chloride gas. This aluminum chloride is recycled in the catalytic cycle of alkylation. 

The cyclopentadienes la-e can be deprotonated by potassium in toluene to give the potassium cyclopentadienides 2a-e [2]. These compounds are very soluble in THF and also in hot benzene or toluene, which is indicative of the presence of essentially monomeric units in solution this is due to an intramolecular donor stabilization by the tentacle function [6]. 

Streitwieser and Boerth studied the kinetic acidities of cycloalkenes with lithium cyclo-hexylamide (LiCHA) in cyclohexylamine for comparison with those of benzene and toluene66. The relative rates of deprotonation and the corresponding equilibrium pK values are tabulated in Table 12. These proton transfer transition states are stabilized by conjugation of the reacting C—H bond with the double bond. 

This novel anodic methoxyiation may proceed via the fluorosulfonium ion B in a Pummerer-type mechanism as shown in Scheme 6.11. In this mechanism, the cation radical A of the sulfide is trapped by a fluoride ion, and this step should suppress side reactions from the cation radical A (such as dimerization and nucleophilic attack on an aromatic ring) even when deprotonation of A is slow due to the weak electron-withdrawing Rf groups or electron-donating substituents on the benzene ring. Since fluoride ions are much weaker nucleophiles compared to methoxide, it is reasonable that the methoxyiation predominates in methanol. 

Fragments in compounds 155—157 exhibit aromatic bond delocalization. The lowest aromaticity is calculated for Af-pyridinium cyclopentadienide 157, with the interfragmental C—N bond shorter than the corresponding one in 155 and 158. The phenolate moiety in 159 has a high NICS value (—4.6 ppm), in agreement with the one for deprotonated phenol (—6.2 ppm compared to —9.7 ppm for benzene, as cited),196 while the acceptor pyridinium counterpart has a NICS value of —5.5 ppm, showing aromatic delocalization. 

Conversion of tight ion pairs into crown ether-separated ion pairs leads in many cases to increased basicity. For example, Dietrich and Lehn (1973) have shown that a homogeneous solution of sodium t-amyloxide in benzene is unable to deprotonate triphenylmethane, whereas the reaction occurs rapidly in the presence of [2.2.2]-cryptand [37]. In THF or diethyl ether, alkali metal enolates do not react with triphenyl- or diphenylmethane (Pierre et al.,... 

Anodic oxidations of hexathioalkyl benzene asterisk compounds were achieved at a Pt anode in AN. In particular, hexa-iso-propylthio-benzene afforded both the primary cation radical and the free radical obtained from the deprotonation (Eq. 10). 

Wittig reactions have been studied and extended by sonochemists. Starting from allylic phosphoranes, it was shown that the initial deprotonation step could be effected with an increased efficiency using butyl lithium in TH F or even in benzene (Scheme 3.23) [122]. The insoluble phosphorane disappears after 5-15 min sonication. This superposition of the two essential roles of sonication is reflected by the change in the stereoselectivity, larger proportions of the trans-diene being formed under irradiation. 

Cumene is generated following a deprotonation step [85]. One of the undesired reactions is multiple alkylahon with propylene. Oligomerization of propylene is also undesired. Beta zeolite is a typical catalyst for this reaction. A series of Beta zeolites synthesized with Si/Af rahos ranging from 20 to 350 were evaluated for the alkylation of benzene with propylene at 423°K and 3 MPa in the presence of benzene alkene molar raho of 7.0. The benzene alkene molar ratio was kept high in order to minimize the undesired reactions. The selectivity to the mono-alkylate product was 92-93% in every case with the balance being the dialkylated product. The activity decreased with increase in Si/Al2 but the selectivity was independent of the Si/A12 ratio [86]. 

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