Nucleophilic aromatic substitution metal-catalyzed

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. 

Chapter 11 focuses on aromatic substitution, including electrophilic aromatic substitution, reactions of diazonium ions, and palladium-catalyzed nucleophilic aromatic substitution. Chapter 12 discusses oxidation reactions and is organized on the basis of functional group transformations. Oxidants are subdivided as transition metals, oxygen and peroxides, and other oxidants. 

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]. 

Substitution of halopurines at C-2 and C-6 has become a well-developed synthetic process, with a wide variety of nucleophilic aromatic substitution and palladium-catalyzed C-N or C-O hond formations exemplified in the literature. The use of selective, sequential substitution reactions on polyhalopurine scaffolds is the basis of an increasing number of combinatorial syntheses of polysubstituted purines, both in solution and on solid phase. The introduction of N-, 0-, or S-substituents has often been combined with transition metal-catalyzed C-C bond-forming reactions (see Section 10.11.7.4.2) and selective N-alkylation (see Section 10.11.5.2.1) to provide versatile routes to purines with multiple, diverse substituents. 

Phase transfer was used to catalyze nucleophilic aromatic substitutions by Makosza et al. in 1974.201 202 Zoltewicz203 has given a good early review of various methods and has compared other techniques that make use of polar solvents, transition metals, and monoelectron transfers. 

Substituted imidazole 1-oxides 228 are predicted to be activated toward electrophilic aromatic substitution, nucleophilic aromatic substitution, and metallation as described in Section 1. Nevertheless little information about the reactivity of imidazole 1-oxides in these processes exists. The reason for this lack may be the high polarity of the imidazole 1-oxides, which makes it difficult to find suitable reaction solvents. Another obstacle is that no method for complete drying of imidazole 1-oxides exists and dry starting material is instrumental for successful metallation. Well documented and useful is the reaction of imidazole 1-oxide 228 with alkylation and acylation reagents, their function as 1,3-dipoles in cycloadditions, and their palladium-catalyzed direct arylation. 

Arylation of amines in combinatorial synthesis has been achieved by nucleophilic aromatic substitution or by metal-catalyzed amine/halogen exchange (Table 3.5). 

Nucleophilic aromatic substitution often requires metal catalysis, as described above. In contrast, alkyl halides undergo reactions with phosphines directly. Nevertheless, metal-catalyzed cross-couplings of these reactive electrophiles have been developed by activation of the nucleophile. 

Oxidative addition of substrates possessing C-X or H-X bonds of medium polarity and of substrates possessing Ar-X bonds that cannot undergo S 2 pathways often occur by concerted pathways involving three-centered transition states more like those of the oxidative additions of nonpolar substrates. The clearest cases in which reactions occiu by concerted pathways are the oxidative additions of aryl halides and sulfonates to paUadium(0) complexes. These reactions have been studied extensively because they are the first step of transition-metal-catalyzed nucleophilic aromatic substitution reactions called cross couplings. The oxidative additions of the O-H and N-H bonds in water, alcohols, and amines also appear to occur by concerted three-centered transition states in many cases. 

Two special chlorination procedures for pentachlorocorannulene and decachloro-corannulene open new avenues for the study of this area (see below). Already mentioned above, 1,2,5,6-tetrabromocorannulene (18) is a formal precursor of corannulene when using the Rabideau closure, but it is of direct importance for making various corannulene derivatives. The importance of multi-halocorannulenes stems from the variety and reliability of nucleophilic aromatic substitutions and related transition-metal catalyzed couplings with nucleophiles. 

Synthetically important substitutions of aromatic compounds can also be done by nucleophilic reagents. There are several general mechanism for substitution by nucleophiles. Unlike nucleophilic substitution at saturated carbon, aromatic nucleophilic substitution does not occur by a single-step mechanism. The broad mechanistic classes that can be recognized include addition-elimination, elimination-addition, and metal-catalyzed processes. (See Section 9.5 of Part A to review these mechanisms.) We first discuss diazonium ions, which can react by several mechanisms. Depending on the substitution pattern, aryl halides can react by either addition-elimination or elimination-addition. Aryl halides and sulfonates also react with nucleophiles by metal-catalyzed mechanisms and these are discussed in Section 11.3. 

This chapter is concerned with reactions that introduce or replace substituent groups on aromatic rings. The most important group of reactions is electrophilic aromatic substitution. The mechanism of electrophile aromatic substitution has been studied in great detail, and much information is available about structure-reactivity relationships. There are also important reactions which occur by nucleophilic substitution, including reactions of diazonium ion intermediates and metal-catalyzed substitution. The mechanistic aspects of these reactions were discussed in Chapter 10 of Part A. In this chapter, the synthetic aspects of aromatic substitution will be emphasized. 

The introduction of nucleophiles onto five membered heterocycles through non-catalyzed aromatic nucleophilic substitution is of little synthetic value, since the comparatively high electron density of the aromatic ring makes the nucleophilic attack unfavourable. The introduction of transition metal catalyzed carbon-heteroatom bond forming reactions overcame this difficulty and led to a rapid increase in the number of such transformations. 

Aryl- and heteroaryl halides can undergo thermal or transition metal catalyzed substitution reactions with amines. These reactions proceed on insoluble supports under conditions similar to those used in solution. Not only halides, but also thiolates [76], nitro groups [76], sulfinates [77,78], and alcoholates [79] can serve as leaving groups for aromatic nucleophilic substitution. 

Noteworthy as more frequent than previously are applications of transition metal catalyzed cross-couplings in their numerous modifications to functionalize the pyrrole ring, which often can be formally classified as aromatic nucleophilic substitutions <2006EJ03043>. 

The author believes that students are well aware of the basic reaction pathways such as substitutions, additions, eliminations, aromatic substitutions, aliphatic nucleophilic substitutions and electrophilic substitutions. Students may follow undergraduate books on reaction mechanisms for basic knowledge of reactive intermediates and oxidation and reduction processes. Reaction Mechanisms in Organic Synthesis provides extensive coverage of various carbon-carbon bond forming reactions such as transition metal catalyzed reactions use of stabilized carbanions, ylides and enamines for the carbon-carbon bond forming reactions and advance level use of oxidation and reduction reagents in synthesis. 

The mechanism classification and the overall transformation classification are orthogonal to each other. For example, substitution reactions can occur by a polar acidic, polar basic, free-radical, pericyclic, or metal-catalyzed mechanism, and a reaction under polar basic conditions can produce an addition, a substitution, an elimination, or a rearrangement. Both classification schemes are important for determining the mechanism of a reaction, because knowing the class of mechanism and the overall transformation rales out certain mechanisms and suggests others. For example, under basic conditions, aromatic substitution reactions take place by one of three mechanisms nucleophilic addition-elimination, elimination-addition, or SrnL If you know the class of the overall transformation and the class of mechanism, your choices are narrowed considerably. 

The introduction or replacement of substituents on aromatic rings by substitution reactions is one of the most fundamental transformations in organic chemistry. On the basis of the reaction mechanism, these substitution reactions can be divided into (a) electrophilic, (b) nucleophilic, (c) radical, and (d) transition metal catalyzed. In this chapter we consider the electrophilic and nucleophilic substitution mechanisms. Radical substitutions are dealt with in Chapter 11 and transition metal-catalyzed reactions are discussed in Chapter 9 of Part B. 

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