Diaryliodonium salt

The carbonylation of aryl iodides in the presence of alkyl iodides and Zn Cu couple affords aryl alkyl ketones via the formation of alkylzinc species from alkyl iodides followed by transmetallation and reductive elimination[380]. The Pd-catalyzed carbonylation of the diaryliodonium salts 516 under mild conditions in the presence of Zn affords ketones 517 via phenylzinc. The a-diketone 518 is formed as a byproduct[381],... 

The UV cure system contains an epoxy or a vinyl ether functionalized PDMS polymer and a photo catalyst [36]. This latter, a diaryliodonium salt is photolyti-cally decomposed to form an active acid that polymerizes the epoxy or vinyl ether groups and crosslinks the network. 

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... 

As part of a later investigation into palladium-catalyzed reactions of diaryliodonium salts 220, Chen and Zhou found that reaction with amidoximes in the presence of carbon monoxide also gave 1,2,4-oxadiazoles (Equation 41) <2002SC887>. 

Effect of Viscosity on the Rate of Photosensitization of Diaryliodonium Salts by Anthracene... 

Photosensitization of diaryliodonium salts by anthracene occurs by a photoredox reaction in which an electron is transferred from an excited singlet or triplet state of the anthracene to the diaryliodonium initiator.13"15,17 The lifetimes of the anthracene singlet and triplet states are on the order of nanoseconds and microseconds respectively, and the bimolecular electron transfer reactions between the anthracene and the initiator are limited by the rate of diffusion of reactants, which in turn depends upon the system viscosity. In this contribution, we have studied the effects of viscosity on the rate of the photosensitization reaction of diaryliodonium salts by anthracene. Using steady-state fluorescence spectroscopy, we have characterized the photosensitization rate in propanol/glycerol solutions of varying viscosities. The results were analyzed using numerical solutions of the photophysical kinetic equations in conjunction with the mathematical relationships provided by the Smoluchowski16 theory for the rate constants of the diffusion-controlled bimolecular reactions. 

Figure 1. Representative anthracene fluorescence profile during the photosensitization of diaryliodonium salts in pure propanol at 30°C.

Figure 2. Profile of anthracene fluorescence at 425 nm obtained during photosensitization of diaryliodonium salt in pure propanol at 30°C.

The discrepancies between the experimental data and the behavior predicted using the Smoluchowski-Stokes-Einstein model for ksenfluor and ksenphos likely arise from the inadequacies of the simple Smoluchowski-Stokes-Einstein analysis for application to the anthracene/diaryliodonium salt molecular system. For example, the Smoluchowski analysis assumes that the reacting molecules are spherical in... 

Liu, Z. and Chen, Z., Studies on the application of hypervalent iodine in synthesis. 11. Synthesis of arylphosphonates by arylation of phosphite anions using diaryliodonium salts, Synthesis, 373, 1993. 

Diarylide yellow pigments, 74 317 79 433 Diaryliodonium salt photoinitiators, 74 270 Diaryliodonium salts, 79 108 photolysis of, 70 414... 

This basic approach to chemical amplification was subsequently extended by Ito et al. [3] through resist formulations incorporating appropriately chosen triaryl sulfonium or diaryliodonium salt. For example, end-capped poly(phthalaldehyde) used in combination with an onium salt photoacid generator is an excellent self-... 

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]. 

Arenediazonium salts reacted with tetramethyltin under very mild conditions in acetonitrile yielding the corresponding toluenes [63] and this reaction could be carried out in aqueous media, as well [64] (Scheme 6.29). Similar to the Heck reactions discussed in 6.1.1, a one-pot procedure could be devised starting from anilines, with no need for the isolation of the intermediate diazonium salts. The pH of the solutions should always be kept below 7 in order to avoid side reactions of the diazonium salts, however, unlike with the Heck reactions, HCl or H2SO4 can also be used. Since organotin compounds are easily hydrolysed in acidic solutions, a careful choice of the actual pH is required to ensure fast and clean reactions. Diaryliodonium salts are hydrolytically stable and also react smoothly with various organotin compounds (Scheme 6.29) [65]. 

All the 1-pyrenylbismuthonium salts photochemically decompose (2ex > 320 nm / > 150 mW cm 2) to generate their respective protic acids, accompanied by the formation of bismuth(III) compounds and pyrene (Scheme 25). The quantum yields of the photodecomposition (<7>dcc) in acetonitrile were determined by chemical actinometry to be 0.20-0.22. These values are comparable to the values reported for the triarylsulfonium and diaryliodonium salts (dec = 0.17-0.22) [98, 99]. 

This procedure represents a novel, convenient, and fairly general method for preparing y-aryl-/3-diketones. By this method the submitters have phenylated the dianion of 1-phenyl-1,3-butanedione (61%), 2,4-heptanedione (98%), 2,4-nonanedione (78%), 2,4-tridecanedione (53%), and 3,5-heptanedione (50%).6 Substituted diaryliodonium salts have also been used to produce l-(4-chlorophenyl)-2,4-pentadione (44%), 4-(4-methyl-phenyl)-l-phenyl-l,3-butanedione (44%), and l-(4-methyl-phenyl)-2,4-nonanedione (21%).6 Under these conditions no more than a trace, if any, of arylation at the a-position of the /3-diketones was observed by gas chromatography analysis. 

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 synthetic potential of palladium-mediated cross-coupling reactions (Heck, Suzuki, Stille, Sonogashira, Buchwald-Hartwig) led to the search for a practical synthesis of p-[ F]fluoroiodo- and p-[ F]fluorobromobenzene. p-[ F]Fluoroio-dobenzene (G, X = iodine) can be obtained in poor yield from p F]fluoride and a trimethylammonium precursor (P7). p-p F]Fluorobromobenzene can be prepared in a more reproducible way from 5-bromo-2-nitrobenzaldehyde (radiochemical yields > 70%). The synthesis involves a two-step procedure radiofluorination (F for NO2 substitution), then a catalysed decarbonylation [190,191]. Also very efficient is the one-step reaction of p F]fluoride with a suitable diaryliodonium salt (P6) giving >70% radiochemical yield [192-194]. 

The exceptional case where no activating group is required is the use of diaryliodonium salts as precursors for labelling, permitting the fluorine-18-labelling of relatively electron-rich structures [192-194], A recent example of successful application is the preparation of 5-[ F]fluorouracil in 40% radiochemical yield (Scheme 44) [202], However, this methodology appears to be relatively difficult to use with complex structures [203-205],... 

A. Shah, V.W. Pike, D.A. Widdowson, The synthesis of [F-18]fluoroarenes from the reaction of cyclotron-produced [F-18]fluoride ion with diaryliodonium salts, J. Chem. Soc. Perkin Trans. I Organic and Bio-Organic Chemistry 13 (1998) 2043-2046. 

Several dyes have been found to sensitize the cationic polymerization of cyclohexene oxide, epichlorohydrin, and 2-chloroethyl vinyl ether initiated by diaryliodonium salts (109,110). Acridinium dyes such as acridine orange and acridine yellow were found to be effective sensitizers. One example of a benzothiazolium dye (setoflavin T) was also reported, but no other class of dye nor any other example of a dye absorbing at longer wavelengths were discovered. Crivello and Lam favored a sensitization mechanism in which direct energy transfer from the dye to the diaryliodonium salt occurred. Pappas (12,106) provided evidence that both energy transfer and electron transfer sensitization were feasible in this system. 

Scheme VI. Processing of poly(t-BOC-styrene)-onium salt resists. The steps are (1) photogeneration of an extremely strong protonic acid from a triaryl-sulfonium or diaryliodonium salt and (2) baking, which allows acid-catalyzed deblocking of the t-BOC groups. Thus, irradiated areas of the polymer are converted to a much more polar form.

Diaryliodonium salts (diaryl-A3-iodanes) are widely used as arylating agents. There are a number of methods available for their synthesis typically involving two or three steps.378,379 A recent one-pot approach, however, offers a simple and high-yielding access to unsymmetrical diaryliodonium triflates using meto-chloroperbenzoic acid (mCPBA) as the oxidant380 [Eq. (4.111)]. Moreover, symmetrical diaryliodonium salts can directly be prepared from iodine and arenes without the use of expensive aryl iodides [Eq. (4.112)]. 

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