Ethere electrophilic aromatic substitution

The six-position may be functionalized by electrophilic aromatic substitution. Either bromination (Br2/CH2Cl2/-5°) acetylation (acetyl chloride, aluminum chloride, nitrobenzene) " or chloromethylation (chloromethyl methyl ether, stannic chloride, -60°) " affords the 6,6 -disubstituted product. It should also be noted that treatment of the acetyl derivative with KOBr in THF affords the carboxylic acid in 84% yield. The brominated crown may then be metallated (n-BuLi) and treated with an electrophile to form a chain-extender. To this end, Cram has utilized both ethylene oxide " and dichlorodimethyl-silane in the conversion of bis-binaphthyl crowns into polymer-bound resolving agents. The acetylation/oxidation sequence is illustrated in Eq. (3.54). 

The general approaches for the synthesis of poly(arylene ether)s include electrophilic aromatic substitution, nucleophilic aromatic substitution, and metal-catalyzed coupling reactions. Poly(arylene ether sulfone)s and poly(arylene ether ketone)s have quite similar structures and properties, and the synthesis approaches are quite similar in many respects. However, most of the poly(arylene ether sul-fone)s are amorphous while some of the poly(arylene ether)s are semicrystalline, which requires different reaction conditions and approaches to the synthesis of these two polymer families in many cases. In the following sections, the methods for the synthesis of these two families will be reviewed. 

The synthesis of 3-aryltetrahydroisoquinolines was accomplished by electrophilic aromatic substitution of polysubstituted phenols and phenyl ethers with Lewis acid-generated tosyliminium ions of 2-tosyl-3-methoxytetrahydroisoquinoline derivatives <00SL801>. In addition isoquinoline was reported to react with N-tosylated (R)- or (S)-amino acid fluorides to afford optically active dihydroimidazoisoquinolinones. The reaction proceeds via acylation followed by attack of the tosylamino group at Cl of the intermediate 2-tosylaminoacylisoquinolinium salt <00TL5479>. 

C-H activation at a primary benzylic site was the key step in very short syntheses of lig-nans 206 and 207 (Scheme 14.27) [138]. Even though both the substrate 203 and the vinyl-diazoacetate 204 contain very electron-rich aromatic rings, C-H activation to form 205 (43% yield and 91% ee) is still possible because the aromatic rings are sterically protected from electrophilic aromatic substitution by the carbenoid. Reduction of the ester in (S)-205 followed by global deprotection of the silyl ethers completes a highly efficient three-step asymmetric total synthesis of (-i-)-imperanene 206. Treatment of (R)-205 in a more elaborate synthetic sequence of a cascade Prins reaction/electrophilic substitution/lacto-nization results in the total synthesis of a related lignan, (-)-a-conidendrin 207. 

Phenol-formaldehyde prepolymers, referred to as novolacs, are obtained by using a ratio of formaldehyde to phenol of 0.75-0.85 1, sometimes lower. Since the reaction system is starved for formaldehyde, only low molecular weight polymers can be formed and there is a much narrower range of products compared to the resoles. The reaction is accomplished by heating for 2 1 h at or near reflux temperature in the presence of an acid catalyst. Oxalic and sulfuric acids are used in amounts of 1-2 and <1 part, respectively, per 100 parts phenol. The polymerization involves electrophilic aromatic substitution, first by hydroxymethyl carboca-tion and subsequently by benzyl carbocation—each formed by protonation of OH followed by loss of water. There is much less benzyl ether bridging between benzene rings compared to the resole prepolymers. 

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... 

In a manifestation of the reaction shown above, quinoline rings have also been formed by the cycloaddition of /V-arylketenimines 543 with 3,4-dihydro-2//-pyran 455 under high-pressure conditions (Scheme 100) <2001H(55)1971>. The reaction is proposed to proceed via the initial formation of 544 by attack of the enol ether on the protonated ketenimine subsequent electrophilic aromatic substitution gives 545. Protonation of the enamine to give 546 is followed by elimination to produce 547. Protection of the alcohol with 455 gives 548. 

Electrophilic aromatic substitution is also possible from triphenylborane [11] (readily accessible by reacting boron trifluoride with phenylmagnesium bromide in anhydrous ether) [22] (Scheme 6). 

CHAPTER 7 CHAPTER 8 CHAPTER 10 CHAPTER 11 CHAPTER 15 CHAPTER 17 CHAPTER 18 Acid-Catalyzed Dehydration of an Alcohol 313 Electrophilic Addition to Alkenes 330 Grignard Reactions 443 The Williamson Ether Synthesis 500 The Diels-Alder Reaction 684 Electrophilic Aromatic Substitution 757 Nucleophilic Additions to Carbonyl Groups 841 Formation of Imines 851 Formation of Acetals 856... 

We shall return to reactions of phenols and phenyl ethers when we consider directing effects in electrophilic aromatic substitution in other reactions and in Friedel-Crafts reactions in particular. 

If the anodic oxidation of N-alkylanilines is performed in the presence of nucleophiles like enol ethers, nucleophilic substitution in the of-position to nitrogen by the enol ether can be observed in low yields. The electrophilic intermediate is the N-aryl iminium ion or the N-aryl imine after loss of two electrons and one or two protons. These intermediates add to the enol ether to give acetals (up to 26%) as addition products, or the first addition step is followed by an electrophilic aromatic substitution to form tetrahydroqui-nolines (13-39%) [47]. It should be noted at this point that better results for the nucleophilic a-substitution to nitrogen can be obtained with N,N-dialkylanilines (see next subsection). Optimum results, however, are obtained with N-acylated compounds via the intermediate N-acyl iminium ions (see Ref. 8). 

Aminomethylation. Aminals and aminol ethers are activated by sulfur dioxide, thus electrophilic aromatic substitution with electron-rich arenes can be performed. ... 

To the ether electrophile it is a substitution process, but to the benzene nucleophile it is an electrophilic aromatic substitution that has two steps, electrophile addition and then rearomatization. The problem space for the overall process must incorporate both the substitution and rearomatization and also the fact that it happens twice (Fig. 10.8). 

In an analogous reaction, where anisole (0.5 mole), chloromethyl ether (0.1 mole), and REX catalyst (2 gm) were stirred for 14 hours at room temperature, a 28% yield of a mixture of 2,2 -dimethoxydiphenyl-methane, 2,4 -dimethoxydiphenylmethane, and 4,4 -dimethoxydi-phenylmethane in the ratio of 1 5.7 5.4 was obtained. No 1 1 adduct (chloromethyl- or methoxymethylanisole) was observed. The lower reaction temperatures required with anisole reflect the activating effect of an electron-donating substituent in electrophilic aromatic substitution. 

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