Nucleophilic aromatic substitution examples

Nucleophilic aromatic substitutions involving loss of hydrogen are known. The reaction usually occurs with oxidation of the intermediate either intramoleculady or by an added oxidizing agent such as air or iodine. A noteworthy example is the formation of 6-methoxy-2-nitrobenzonitrile from reaction of 1,3-dinitrobenzene with a methanol solution of potassium cyanide. In this reaction it appears that the nitro compound itself functions as the oxidizing agent (10). 

Other aryl halides that give stabilized anions can undergo nucleophilic aromatic substitution by the addition-elimination mechanism. Two examples are hexafluorobenzene and 2-chloropyridine. 

As we ve seen, aromatic substitution reactions usually occur by an electrophilic mechanism. Aryl halides that have electron-withdrawing substituents, however, can also undergo nucleophilic aromatic substitution. For example. 2,4,6-trinitrochlorobenzene reacts with aqueous NaOH at room temperature to give 2,4,6-trinitrophenol. The nucleophile OH- has substituted for Cl-. 

A long series of studies of aromatic nucleophilic substitution included the kinetics of reactions of l-chloro-2,4-bis(trifluoromethylsulfonyl)benzene, 3-nitro-4-chlorophenyl trifluoromethyl sulfone and 2-chlorophenyl trifluoromethyl sulfone with sodium methox-ide or ammonia in methanol . The SO2CF3 group was found to have an enormous accelerating effect, in accord with the value of 1.65, based on the dissociation of anilinium ion. Further examples of the promotion of nucleophilic aromatic substitution by fluoro-substituted sulfonyl groups are given by Yagupol skii and coworkers . 

Some theoretical aspects of thiophene reactivity and structure have also been discussed, for example the kinetics of proton transfer from 2,3-dihydrobenzo[6]thiophenc-2-onc <06JOC8203>, the configuration of imines derived from thiophenecarbaldehydes <06JOC7165>, and the relative stability of benzo[c]thiophene <06T12204>. The kinetics of nucleophilic aromatic substitution of some 2-substituted-5-nitrothiophenes in room temperature ionic liquids have also been investigated <06JOC5144>. 

In more recent work by other researchers, sealed-vessel microwave technology has been utilized to access valuable medicinally relevant heterocyclic scaffolds or intermediates (Scheme 6.120) [240-245]. Additional examples not shown in Scheme 6.120 can be found in the most recent literature (see also Scheme 6.20) [246-249]. Examples of nucleophilic aromatic substitutions in the preparation of chiral ligands for transition metal-catalyzed transformations are displayed in Scheme 6.121 [106,108]. 

A variation of this method led to the generation of bis-benzimidazoles [81, 82], The versatile immobilized ortho-phenylenediamine template was prepared as described above in several microwave-mediated steps. Additional N-acylation exclusively at the primary aromatic amine moiety was achieved utilizing the initially used 4-fluoro-3-nitrobenzoic acid at room temperature (Scheme 7.72). Various amines were used to introduce diversity through nucleophilic aromatic substitution. Cyclization to the polymer-bound benzimidazole was achieved by refluxing for several hours in a mixture of trifluoroacetic acid and chloroform. Individual steps at ambient temperature for selective reduction, cyclization with several aldehydes, and final detachment from the polymer support were necessary in order to obtain the desired bis-benzimidazoles. A set of 13 examples was prepared in high yields and good purities [81]. 

A wide variety of other heterocyclic ring systems can conceivably serve as the conjugated backbone in nonlinear organic molecules. We will give examples from preliminary work on two of these, the thiazole and pyrimidine heterocycle derivatives 65-72 in Table VIII. These two heterocycles were chosen because the appropriate haloderivatives are commercially available as starting materials for nucleophilic aromatic substitution. The pyrimidine derivatives are of particular interest since their absorption edges ( 400 nm) are shifted hypsochromically an additional 30 nm relative even to the pyridines. 

An example of the method described is the synthesis of saphenic acid (47) that has recently been reported by Nielsen et al. [81]. Starting from properly substituted aromatic precursors 92 and 93, the naturally occurring 1,6-disub-stituted phenazine was synthesized in racemic form. Here, the first major step involves an intermolecular nucleophilic aromatic substitution that, due to the substitution pattern, has proved to be relatively unproblematic and after hydrolysis of the acetal yields the o-nitrodiphenylamine 94. Much more difficult is the ring formation leading to the final phenazine, which can best be achieved through a high excess of NaBH4, accompanied by reduction of the methyl ketone. But at 32%, the yield is still rather poor. 

For liquid-phase reactions it is known that they may be enhanced by applying higher pressures if the activation volumes are strongly negative, for example, with Diels-Alder reactions. At pressures up to 600 bar (6 x 10 Pa), Benito-Lopez et al. used fiber-based on-line UV-vis spectroscopy to monitor the nucleophilic aromatic substitution of l-fluoro-4-nitrobenzene with a ten-fold excess of pyrrolidine. ... 

Monoalkylation of a-isocyano esters by using tert-butyl isocyano acetate (R = fBu) has been reported by Schollkopf [28, 33]. Besides successful examples using primary halides, 2-iodopropane has been reported to produce the a-alkylated product (1) as well by this method (KOfBu in THF). In the years 1987-1991, Ito reported several methods for the monoalkylation of isocyano esters, including the Michael reaction under TBAF catalysis as described earlier [31], Claisen rearrangements [34], and asymmetric Pd-catalyzed allylation [35]. Finally, Zhu recently reported the first example of the introduction of an aromatic substituent by means of a nucleophilic aromatic substitution (Cs0H-H20, MeCN, 0°C) in the synthesis of methyl ot-isocyano p-nitrophenylacetate [36]. 

There are not many successful examples of arylation of carbanions by nucleophilic aromatic substitution. A major limitation is the fact that aromatic nitro compounds often react with carbanions by electron-transfer processes.111 However, such substitution can be carried out under the conditions of the SRN1 reaction (see Section 11.4). 

Scheme 11.8 gives some examples of nucleophilic aromatic substitution reactions. 

Tertiary benzylic nitriles are useful synthetic intermediates, and have been used for the preparation of amidines, lactones, primary amines, pyridines, aldehydes, carboxylic acids, and esters. The general synthetic pathway to this class of compounds relies on the displacement of an activated benzylic alcohol or benzylic halide with a cyanide source followed by double alkylation under basic conditions. For instance, 2-(2-methoxyphenyl)-2-methylpropionitrile has been prepared by methylation of (2-methoxyphenyl)acetonitrile using sodium amide and iodomethane. In the course of the preparation of a drug candidate, the submitters discovered that the nucleophilic aromatic substitution of aryl fluorides with the anion of a secondary nitrile is an effective method for the preparation of these compounds. The reaction was studied using isobutyronitrile and 2-fluoroanisole. The submitters first showed that KHMDS was the superior base for the process when carried out in either THF or toluene (Table I). For example, they found that the preparation of 2-(2-methoxyphenyl)-2-methylpropionitrile could be accomplished h... 

New developments in this area include the N-arylation of substituted morpholines, where an aromatic halogen atom is replaced by the morpholine. The first example is of a nucleophilic aromatic substitution. 2-Eluorobenzaldehyde 191 and 2-fluoroacetophenone 192 were reacted with (3i )-3-ethylmorpholine 193 to give the 2-(.3i )-3-ethylmorpholinyl derivatives 194 and 195 in 25% and 23% yields, respectively (Equation 11). The reaction required heating under reflux for several days <1989JOC209>. 

There are a wide number of reports regarding nucleophilic aromatic substitution a to nitrogen in 1,10-phenanthro-line 48. Eor example, the aryllithium reagent 49 adds to 1,10-phenanthroline 48 and on oxidative workup yields... 

Substituted binaphthyl compounds can be synthesized in high optical yields using nucleophilic aromatic substitution reactions in which the chiral leaving groups are alkoxy moieties derived from naturally occurring alcohols28-29. For example, the condensation of 2-(l-alkoxynaphth-2-yl)-4.5-dihydro-4,4-dimethyl-l,3-oxazole with 1-naphthyllithium or 2-methoxy-l-naphthyl 2-magnesium bromide leads to (ft)- or (.S)-(l,T-binaphthyl-2-yl)-4,5-dihydro-4,4-dimethyl-l,3-oxazole derivatives. 

Nucleophilic Aromatic Substitution. A natural extension of alkene addition processes is aromatic nucleophilic substimtion. Again, the ease of the process is highly dependent on the stability of the intermediate carbanion and strong EWGs are needed to facilitate these reactions in solution. The classic example is the... 

Nucleophilic aromatic substitutions 1,3-azoles are more reactive than pyrrole, furan or thiaphene towards nucleophilic attack. Some examples of nucleophilic aromatic substitutions of oxazole, imidazole and thiazoles and their derivatives are given below. In the reaction with imidazole, the presence of a nitro-group in the reactant can activate the reaction because the nitro-group can act as an electron acceptor. 

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