Diaryliodonium salts, arylation with

Diaryliodonium salts react with sodium benzoate to give the aryl benzoates in moderate to good yields (40-85%). Treatment of biphenyleneiodonium sulfate (29) with sodium methoxide failed to give 2-iodo-2 -methoxybiphenyl. However, this product was obtained by an indirect sequence involving the formation of 2-iodo-2 -acetoxybiphenyl (30) by reaction of the biphenyleneiodonium sulfate with sodium acetate in boiling glacial acetic acid. Nearly quantitative yields were obtained when the reaction was catalysed by copper salts. 102... 

Diaryliodonium salts also reacted with enamines to give a-aryl ketones in low yields (370). 

In recent years, a variety of hypervalent iodine reagents have been available. The versatility of these hypervalent organoiodine reagents in organic synthesis has been well recognized. Diaryliodonium salts constitute an important reagent class for the transfer of aryl groups. These iodonium ion salts have been used effectively in C-arylation of a variety of nucleopohiles.112 The arylation of the anion of nitroalkanes with diaryliodonium salts was already reported in 1963.113... 

In a modified version of the Suzuki reaction arylboronates or boranes are utilized instead of arylboronic acid. Under the action of phosphine-free palladium catalysts NaBPh4 and tra(l-naphtyl)borane were found suitable phenyl-sources for arylation of haloaromatics in fully or partially aqueous solutions at 20-80 °C with good to excellent yields (Scheme 6.12) [32-34]. Aryl halides can be replaced by water-soluble diaryliodonium salts, At2IX (X = HSO4, BF4, CF3COO) in the presence of a base both Ar groups take part in the coupling [35]. 

As mentioned above, condensed 1,2,3-triazine derivatives can be arylated by treatment with nitro-activated aryl halides. The only other report of direct arylation of the 1,2,3-triazine system is due to McKillop and Kobylecki, who studied the reaction of l,2,3-benzotriazin-4-one (10, R = H) with diaryliodonium salts in the presence of base. Treatment of 10, R = H, with diphenyl- and di-p-bromophenyliodonium chloride results in exclusive arylation at N2 and gives the corresponding triazinium betaines (77, R = Ph, p-BrCjH4) in good yield. When di-p-tolyliodonium chloride is used, a mixture of the Nj-, Nj-, and 0-arylated... 

The first preparations of diaryliodonium salts have been reported in the 19th century, but refinements and improvements keep appearing to date. In most cases an iodoaryl species containing iodine(III) is coupled with an arene or a derivative of it in a typical electrophilic aromatic substitution. Lithiated, stannylated or silylated aryls and arylboronic acids or borates have been introduced recently in order to avoid harsh conditions and to improve yields. The iodoaryl species may be also formed in situ from arenes and iodine(III) reagents. 

Aryl and heteroaryl (furyl, thienyl) boronic acids are especially suitable for the preparation of their iodonium salts, having the added advantage of better yields and lack of toxicity [108]. Tetraarylborates (sodium or potassium) reacted with (diacetoxyiodo)arenes in acetic acid to afford diaryliodonium salts in excellent yield (Scheme 37). It appears that triarylboranes formed upon reaction of the borates with acetic acid serve actually as the real arylating agents [109]. 

The self-condensation of iodosylbenzene was the first reported synthesis of a diaryliodonium salt back in 1892. The mechanism of the reaction was delineated only recently. This approach served for the synthesis of p-(phenylene)bis-(aryliodonium) salts [47], as well as some oligomers from (diacetoxyiodo)ben-zene and triflic acid [117], followed by coupling with an arene (Scheme 39). Under suitable conditions the same reaction can lead to simple phenyl(aryl)-iodonium triflates [118]. 

Aryl-, as well as heteroaryliodonium salts, belong to the most common, stable, and well investigated class of polyvalent iodine compounds. The preparation and chemistry of aryliodonium salts was extensively covered in several reviews [5,7,9,10]. Diaryliodonium salts have found synthetic application as arylating reagents in reactions with various organic substrates. 

Compounds containing an active methylene group, or the respective carbanions formed in situ, react smoothly with diaryliodonium salts to yield a-arylated products [1]. A recent example of arylation of carbanions under polar, non-cat-alytic conditions is represented by the reaction of diaryliodonium salts with malonates 90 (Scheme 41) [69]. 

The use of diaryliodonium salts for direct arylations of nucleophilic species is a well-established practice. Examples of C-heteroatom bond formation by this approach, including uncatalyzed arylations of dialkyl phosphite, thiocarboxy-late, arylthiosulfonate, dialkyl phosphorothiolate, arylselenolate, and aryltel-lurolate salts with symmetrical diaryliodonium halides, are shown in (Scheme 40) [110-115]. 

Recent progress on the use of hypervalent iodine reagents for the construction of heteroatom-heteroatom bonds is reviewed. Reactions of aryl-A3-iodanes with heteroatom substrates derived from third-row elements and beyond are considered first, and an unusual example of heteroatom-heteroatom bond formation with diaryliodonium salts is then discussed. Finally, the use of sulfonylimino(aryl)iodanes for imidations of phosphorus, sulfur, selenium, and arsenic compounds, including enantioselective transformations (S,Se), and alternate hypervalent iodine approaches to N-sulfonylsulfilimines and N-sulfonylarsinimines are summarized. 

In summary, recent investigations of reactions of aryl-A3-iodanes,ArIL1L2,with heteroatom substrates, derived from third-row elements and beyond, provide examples of P-O, S-O, Se-O, Se-P, Se-S, Te-O, Bi-O and Sb-0 bond formation. Sulfonylimino(aryl)iodanes, ArI = NS02R, are especially useful as imidation reagents, and have been utilized for the construction of P-N, S-N, Se-N, and As-N bonds. Diaryliodonium salts have been employed indirectly for formation of the Se-Se bond. 

Other unsaturated substrates arylated by various diaryl iodonium salts included butenone, acrylic acid, methyl acrylate and acrylonitrile [46]. Allyl alcohols with diaryliodonium bromides and palladium catalysis were arylated with concomitant oxidation for example, from oc-methylallyl alcohol, aldehydes of the general formula ArCH2CH(Me)CHO were formed [47]. Copper acetylide [48] and phenyl-acetylene [49] were also arylated, with palladium catalysis. 

Apart from copper(I)-mediated reactions, few studies of the treatment of vinyliodonium salts with carbanions have appeared. The vinylations of the 2-phenyl- and 2- -hexyl-l,3-indandionate ions shown in equations 222 and 223 are the only reported examples of vinyliodonium-enolate reactions known to this author26,126. ( ,)-l-Dichloroiodo-2-chloroethene has been employed with aryl- and heteroarvllithium reagents for the synthesis of symmetrical diaryliodonium salts (equation 224)149,150. These transformations are thought to occur via the sequential displacement of both chloride ions with ArLi to give diaryl (/ -chlorovinyl)iodanes which then decompose with loss of acetylene (equation 225). That aryl(/ -chlorovinyl)iodonium chlorides are viable intermediates in such reactions has been shown by the conversion of ( )-(/ chlorovinyl)phenyliodonium chloride to diaryliodonium salts with 2-naphthyl- and 2-thienyllithium (equation 226)149,150. 

The caged species may escape geminate recombination and produce various species that can initiate cationic polymerization. Solvent (RH) often participates in these reactions producing protonic acids. As shown in Eq. (44), protonic acids are also formed by reaction of radical cations with aryl radicals or by Friedel-Crafts arylation. Up to 70% of the protonic acid is formed upon photolysis of diaryliodonium salts [205]. In addition to initiation by protons, arenium cations and haloarene radical cations can react directly with monomer. The efficiency of these salts as cationic initiators depends strongly on the counterions. Those with complex anions such as hexafluoroantimonate, hexafluorophosphate, and triflate are the most efficient. 

Arylboronic acids, (ArB(OH)2, react with thiols and copper(II) acetate to give the corresponding alkyl aryl sulfide. " Arylboronic acids also react with N-methylthiosuccinimide, with a copper catalyst, to give the aryl methyl sulfide. " " In the presence of a palladium catalyst, thiophenols react with diaryliodonium salts. 

An early report of the beneficial influence of 1,1-diphenylethylene (DPE) on the yields of alkylaryl ether obtained in the reaction of diaryliodonium salts with sodium alkoxides showed that radical chain reactions compete efficiently with the 0-arylation reaction. By contrast, addition of diphenylpicrylhydrazyl, a stable free radical species, had no significant influence on the yields of products obtained in e absence of additives. In this case, the 0-arylation reaction was considered to be a direct nucleophilic aromatic substitution reaction, without the involvement of any transient covalent intermediate. (Table 2.11)... 

A similar beneficial effect of 1,1-diphenylethylene on the yields of arylation products was later observed in the synthesis of benzonitrile derivatives by reaction of diaryliodonium salts with potassium cyanide and in the reaction of diaryliodonium salts with the sodium salt of nitroalkanes. 7 In the latter case, the reaction was therefore considered to result from intermediate inner-sphere radicals. Some years later. Barton et al. showed that 1,1-diphenylethylene acts as an efficient inhibitor of the radical chain process in the reaction of enolates with diaryliodonium salts. They concluded that the arylation products arose from a non-radical process. 

Diaryliodonium salts react more or less easily with carbonyl compounds to afford the C-arylated derivatives. Depending upon the nature of the substrate, different experimental conditions have been used. These reactions are generally performed in alcoholic solvents (r-BuOH, r-AmOH.) or in DMF, at temperatures ranging from low (- 78°C) to reflux of the solvent. Arylation of simple ketones has been obtained either by reaction of the ketone enolates with an appropriate diaryliodonium salt, i or by reaction of the ketone enol silyl ether with diaryliodonium fluoride. Phenylation of the potassium enolate of acetone (13) with diphenyliodonium bromide (14) afforded a modest yield of the monophenylation product, but the stimulation with solvated electrons led to overreaction due to the subsequent reaction of the iodobenzene, a good SrnI arylating agent under these conditions. 9... 

In the case of P-diketones, a mixture of C- and O-arylated products were obtained in the reaction of l,3"diketones with diaryliodonium salts, the 0-aryl product being obtained generally in low yields. This ambident reactivity of 1,3-diketone derivatives was observed in different cases sterically hindered reactants,2 88 polybenzoylmethane derivatives and dimedone. ... 

Arylation at the y-position has been reported in the case of a number of p-diketones, when the dianions of these substrates were treated with diaryliodonium salts. l... 

The reaction of cyclohexanone enamines (26) with diaryliodonium salts gave only poor yields of the a-aryl ketones (27) after hydrolysis. ... 

The reaction of phenols with diaryliodonium salts leads to the diaryl ethers in modest to good yields, depending on the substrate and the reaction conditions.31 0>5l-i03 number of studies have dealt with this reaction as it was involved in the synthetic sequence towards diaryl ethers of biological importance, such as bisbenzylisoquinoline alkaloidsl04 or thyronine and tyrosine derivatives.105 The reaction requires relatively harsh conditions, as it is performed under reflux of the solvent. In the case of unsymmetrical diaryliodonium salts, the less electron-rich aryl group of the iodonium salt is preferentially transferred. 

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