Halides aryl, substitution reactions

The addition of Grignard reagents to isocyanates gives, after hydrolysis, N-substituted amides. This is a very good reaction and can be used to prepare derivatives of alkyl and aryl halides. The reaction has also been performed with... 

This method ensures the deposition of very reactive metal nanoparticles that require no activation steps before use. We shall review here the following examples of catalytic reactions that are of interest in line chemical synthesis (a) the hydrogenation of substituted arenes, (b) the selective hydrogenation of a, 3-unsaturated carbonyl compounds, (c) the arylation of alkenes with aryl halides (Heck reaction). The efficiency and selectivity of commercial catalysts and of differently prepared nanosized metal systems will be compared. 

Makosza et al.115 have also reported similar reactions with a 3-substituted oxindol and an aryl halide. The reaction occurs only if the aryl halide is activated by an electron-withdrawing substituent. 

The reactivities of aryl halides, such as the halobenzenes, are exceedingly low toward nucleophilic reagents that normally effect displacements with alkyl halides and activated aryl halides. Substitutions do occur under forcing conditions of either high temperatures or very strong bases. For example, chlorobenzene reacts with sodium hydroxide solution at temperatures around 340° and this reaction was once an important commercial process for the production of benzenol (phenol) ... 

Separation of the p-nitro-substituted aryl halide and reaction with phenoxide ion complete the synthesis. 

Vinylic substitution with aryl halides. This reaction can be effected with catalysis by Pd(OAc)2 and a phosphine yields are generally improved when tri-o-... 

Arynes are generated from aryl halides by reaction with strong bases. The final outcome of the reaction is substitution of the halide. 

Such a mechanism has been hypothesized for the reaction of aryl halides substituted by strong electron-donating groups.838,845 4-Chloroaniline (239), for example, reacts in the triplet state to give a phenyl cation 240, apparently of triplet character (Jt501), which has a selective reactivity toward Jt-, but not n-, nucleophiles (Scheme 6.94), in contrast to the unselective reactions of common singlet aryl cations.847 Interestingly, the cation is added to an alkene to yield 241 even in nucleophilic methanol. 

By considering Schemes 3.1-3.4, we can easily see the wide versatility and high synthetic value of the new and rich aromatic chemistry involving Pd-catalyzed reactions of aryl halides. These reactions offer unique methods for carbon-carbon bond formation, which are impossible or difficult to achieve by conventional means. A revolution and large expansion occurred in aromatic substitution reactions on the discovery of these aryl halide reactions. 

Interestingly, a host of aryl amines, including diphenylamine (Equation 10.23) and alkyl-substituted aryl amines can now readily be prepared from the corresponding aryl halides on reaction of the latter with amine using a palladium catalyst such as tri-t-butylphosphinepalladium(II) in toluene/water with potassium hydroxide (KOH) and an A, A, iv-trimethylcetylammonium bromide [Ci6H33N(CH3)3 Br ] phase transfer catalyst (Chapter 5). ... 

These reactions follow first-order kinetics and proceed with racemisalion if the reaction site is an optically active centre. For alkyl halides nucleophilic substitution proceeds easily primary halides favour Sn2 mechanisms and tertiary halides favour S 1 mechanisms. Aryl halides undergo nucleophilic substitution with difficulty and sometimes involve aryne intermediates. 

The diazonium salts 145 are another source of arylpalladium com-plexes[114]. They are the most reactive source of arylpalladium species and the reaction can be carried out at room temperature. In addition, they can be used for alkene insertion in the absence of a phosphine ligand using Pd2(dba)3 as a catalyst. This reaction consists of the indirect substitution reaction of an aromatic nitro group with an alkene. The use of diazonium salts is more convenient and synthetically useful than the use of aryl halides, because many aryl halides are prepared from diazonium salts. Diazotization of the aniline derivative 146 in aqueous solution and subsequent insertion of acrylate catalyzed by Pd(OAc)2 by the addition of MeOH are carried out as a one-pot reaction, affording the cinnamate 147 in good yield[115]. The A-nitroso-jV-arylacetamide 148 is prepared from acetanilides and used as another precursor of arylpalladium intermediate. It is more reactive than aryl iodides and bromides and reacts with alkenes at 40 °C without addition of a phosphine ligandfl 16]. 

The 2-substituted 3-acylindoles 579 are prepared by carbonylative cycliza-tion of the 2-alkynyltrifluoroacetanilides 576 with aryl halides or alkenyl tri-flates. The reaction can be understood by the aminopalladation of the alkyne with the acylpalladium intermediate as shown by 577 to generate 578, followed by reductive elimination to give 579[425]. 

The strength of their carbon-halogen bonds causes aryl halides to react very slowly in reactions in which carbon-halogen bond cleavage is rate determining as m nude ophilic substitution for example Later m this chapter we will see examples of such reactions that do take place at reasonable rates but proceed by mechanisms distinctly dif ferent from the classical S l and 8 2 pathways... 

Noticeably absent from Table 23 3 are nucleophilic substitutions We have so far seen no nucleophilic substitution reactions of aryl halides m this text Chlorobenzene for example is essentially inert to aqueous sodium hydroxide at room temperature Reac tion temperatures over 300°C are required for nucleophilic substitution to proceed at a reasonable rate... 

The generally accepted mechanism for nucleophilic aromatic substitution m nitro substituted aryl halides illustrated for the reaction of p fluoromtrobenzene with sodium methoxide is outlined m Figure 23 3 It is a two step addition-elimination mechanism, m which addition of the nucleophile to the aryl halide is followed by elimination of the halide leaving group Figure 23 4 shows the structure of the key intermediate The mech anism is consistent with the following experimental observations... 

The reaction between an alkoxide ion and an aryl halide can be used to prepare alkyl aryl ethers only when the aryl halide is one that reacts rapidly by the addition-elim mation mechanism of nucleophilic aromatic substitution (Section 23 6)... 

A second general reaction that proceeds by an SrnI mechanistic pattern involves aryl halides. Aryl halides undergo substitution by eertain nueleophiles by a ehain mechanism of the SrnI class.Many of the reactions are initiated photochemically, and most have been conducted in liquid ammonia solution. 

Unlike elimination and nucleophilic substitution reactions, fonnation of organo-lithium compounds does not require that the halogen be bonded to 5/) -hybiidized car bon. Compounds such as vinyl halides and aryl halides, in which the halogen is bonded to sp -hybiidized carbon, react in the sane way as alkyl halides, but at somewhat slower rates. 

The most common types of aryl halides in nucleophilic aromatic substitutions are those that bear- o- or p-nitro substituents. Among other classes of reactive aryl halides, a few merit special consideration. One class includes highly fluorinated aromatic compounds such as hexafluorobenzene, which undergoes substitution of one of its fluorines on reaction with nucleophiles such as sodium methoxide. 

Elimination-addition mechanism (Section 23.8) Two-stage mechanism for nucleophilic aromatic substitution. In the first stage, an aryl halide undergoes elimination to form an aryne intermediate. In the second stage, nucleophilic addition to the aryne yields the product of the reaction. 

Available information on the mechanism of cyclocondensation is rather contradictory. According to one hypothesis, both the condensation of aryl halides with copper acetylides and the cyclization occur in the same copper complex (63JOC2163 63JOC3313). An alternative two-stage reaction route has also been considered condensation followed by cyclization (66JOC4071 69JA6464). However, there is no clear evidence for this assumption in the literature and information on the reaction of acetylenyl-substituted acids in conditions of acetylide synthesis is absent. 

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