Arylation mechanisms

This last arylation mechanisms is specially interesting because ... 

The GaCls-promoted reaction of alkynylsilanes with arenes, fhen treatment wifh MeLi followed by hydrolysis, yields -arylvinylsilanes (Scheme 10.206) [538]. When D2O is added in fhe hydrolysis step, the a-carbon of fhe vinylsilane product is deuterated. This indicates fhe presence of vinylgallium species in fhe reaction mixture. The arylation mechanism probably involves the Friedel-Crafts-type reaction of GaClj-coordinated alkynylsilanes at the -position. 

Scheme 4 A prototypical concerted metalation-deprotonation (CMD) direct arylation mechanism...

A final common arylation mechanism also involves C-H bond palladation with a Pd(II) catalyst, but then a transmetallation with an organometallic such as a boronic acid. Reductive elimination to form the desired product also releases Pd(0) and this species must be oxidized back to the active Pd(II) catalyst. A key aspect of this process is developing an oxidative system that does not result in homo-coupling of the aryl boronic acid (Scheme 9). 

The mechanisms of these two cyclization reactions appear fairly different. While the xanthone synthesis would appear to follow a simple palladium migration/arylation mechanism, the fluoren-9-one synthesis has been subjected to isotope labeling experiments (Scheme 12), which indicate that more than one mechanistic pathway may apply. It turns out that the deuterium that replaces the iodide after palladium migration comes not only from the imidoyl position, but also from the pendent aromatic ring used to trap the migrated palladium via arylation. Such results can... 

PVC/PO + poly(ethylene-co- alkyl, aryl. mechanical and impact performance Williams and Ilenda, 1993... 

The thermal decomposition reaction of a diaroylperoxide, (ArCOO)2, in a liquid arene, Ar, furnishes a biaryl, Ar-Ar [101-107]. At elevated temperatures the diaroyl peroxide dissociates by the homolytic pathway to generate the arylcarboxy-radicals, ArCOO, which are prone to rapid decarboxylation forming the aryl radicals, Ar. The latter react with the arene, e.g. benzene, by the free-radical arylation mechanism, closely similar to the classical Gomberg-Bachmann-Hey reaction pathway, to give the biaryls, Ar-Ar, in moderate to good yields [101-103], Scheme 28. 

Recently, it was reported that pyridine N-oxides and pyridazine N-oxide undergo 2-arylation efficiently in the presence of a bulky ligand (Equations 10.66 and 10.67) [100, 101], with both reactions perhaps involving a nucleophiUc arylation mechanism. 

A somewhat different alkylation (arylation) mechanism involves the reactions of GSH with unsaturated compounds like divinylsulfone, fV-ethyl-maleimide (51a, b), and several quinones. The adducts with 1,4-naphthoquinone and also 2-methyl—1,4-naphthoquinone have been prepared (52). 

Arylations under metal-catalyzed conditions are generally suggested to proceed by transfer of one aryl group to the metal to create a high oxidation state ArM complex, followed by reductive elimination with the nucleophile, which has either coordinated before (Pd) or after (Cu) the step with At2lX (Scheme Id). Catalytic cycles involving Pd /Pd and CuVCu are often described, but the precise arylation mechanisms are stiU a matter of debate and are not covered here [37-43]. Copper-catalyzed reactions are often performed in dichloromethane (DCM) or 1,2-dichloroethane (DCE), using either a copper(l) or copper(II) source, whereas the Pd-catalyzed conditions vary more. 

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. 

I.l.IJ Reactions nitlr 1,2-, 1.3-. ami 1.4-dienes. The reaction of conjugated dienes with aryl and alkenyl halides can be explained by the following mechanism. Insertion of a conjugated 1.3-diene into an aryl or alkenylpalladium bond gives the T-allvlpalladium complex 243 as an intermediate, which reacts further... 

The o-keto ester 513 is formed from a bulky secondary alcohol using tricy-clohexylphosphine or triarylphosphine, but the selectivity is low[367-369]. Alkenyl bromides are less reactive than aryl halides for double carbonyla-tion[367], a-Keto amides are obtained from aryl and alkenyl bromides, but a-keto esters are not obtained by their carbonylation in alcohol[370]. A mechanism for the double carbonylation was proposed[371,372],... 

The alkylphenylacetyi chloride 843 and benzoyl chloride undergo decarbo-nylative cross-condensation to give the enone 845 in the presence of EtiNf723]. The reaction is e.xplained by the insertion of the ketene 844 into the Pd-aryl bond and, 3-elimination. To support this mechanism, o, d-unsaturuted ketones are obtained by the reaction of ketenes with aroyl chlorides[724]. 

Lithiation at C2 can also be the starting point for 2-arylatioii or vinylation. The lithiated indoles can be converted to stannanes or zinc reagents which can undergo Pd-catalysed coupling with aryl, vinyl, benzyl and allyl halides or sulfonates. The mechanism of the coupling reaction involves formation of a disubstituted palladium intermediate by a combination of ligand exchange and oxidative addition. Phosphine catalysts and salts are often important reaction components. 

Rearrangement to an open chain imine (165) provides an intermediate whose acidity toward lithiomethylthiazole (162) is rather pronounced. Proton abstraction by 162 gives the dilithio intermediate (166) and regenerates 2-methylthiazole for further reaction. During the final hydrolysis, 166 affords the dimer (167) that could be isolated by molecular distillation (433). A proof in favor of this mechanism is that when a large excess of butyllithium is added to (161) at -78°C and the solution is allowed to warm to room temperature, the deuterolysis affords only dideuterated thiazole (170), with no evidence of any dimeric product. Under these conditions almost complete dianion formation results (169), and the concentration of nonmetalated thiazole is nil. (Scheme 79). This dimerization bears some similitude with the formation of 2-methylthia-zolium anhydrobase dealt with in Chapter DC. Meyers could confirm the independence of the formation of the benzyl-type (172) and the aryl-type... 

The method has not been studied extensively and is restricted to the preparation of alkyl-, aryl-, or alkoxy-substituted thiazoles mostly in 2-, 5-, or 2,5-positions. Yields ranged from 45 to 80%. Sometimes this method gives good results when the usual Hantzsch s synthesis fails. There has been very little speculation about the mechanism of this reaction. 

The general mechanism of the rearrangement of aryl and diaryl-thiazoles seems to exclude the zwitterion route. Instead it takes place through bending of thiazoles bonds (98.213). Moreover, tricyclic sul-fonium cation intermediates, after irradiation of deuterated phenyl-thiazoles, have been suggested by several workers (98). 

A key step in the reaction mechanism appears to be nucleophilic attack on the alkyl halide by the negatively charged copper atom but the details of the mechanism are not well understood Indeed there is probably more than one mechanism by which cuprates react with organic halogen compounds Vinyl halides and aryl halides are known to be very unreactive toward nucleophilic attack yet react with lithium dialkylcuprates... 

Aryl halides react too slowly to undergo substitution by the Sn2 mechanism with the sodium salt of diethyl malonate and so the phenyl substituent of phenobarbital cannot be introduced in the way that alkyl substituents can... 

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... 

Second order kinetics is usually interpreted m terms of a bimolecular rate determining step In this case then we look for a mechanism m which both the aryl halide and the nucleophile are involved m the slowest step Such a mechanism is described m the fol lowing section... 

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... 

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

In each of the following reactions an amine or a lithium amide derivative reacts with an aryl halide Give the structure of the expected product and specify the mechanism by which it is formed... 

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)... 

You learned in Section 17 8 of the relationship among hemiacetals ketones and alcohols the for mation of phenol and acetone is simply an example of hemiacetal hydrolysis The formation of the hemiacetal intermediate is a key step in the synthetic procedure it is the step in which the aryl—oxygen bond is generated Can you suggest a reasonable mechanism for this step" ... 

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