Transfer reagent

Sulfonyloxaziridines were recently proposed as O-transferring reagents. Oxaziridine (89) converted thioethers to sulfoxides (90) and diaryl disulfides into their 5-oxides (91) (78TL5171). Epoxidations are also possible (81TL917). 

Synthesis of terminal olefine from ketones or esters via a Ti methylene transfer reagent. 

Although steroidal spiro oxiranes are difficult to obtain stereochemically pure by peracid epoxidations of exocyclic methylenes,the recently developed methylene transfer reagents, dimethylsulfonium methylide and di-methylsulfoxonium methylide in tetrahydrofuran, proved useful in the stereoselective transformation of steroid ketones to a- and -oxiranes, (87) and (88), respectively. ... 

In a further extension of this reaction Winstein and Dauben showed that the action of the methylene-transfer reagent (1) on A -cycloal-kenols, e.g., (2), proceeds by stereospecific cis addition to give the cw-cyclo-propyl carbinol (5). It was also observed that both the rate and yield of the hydroxyl-assisted reaction are increased substantially. It has been suggested that the high stereoselectivity observed in these instances is best explained by complex formation or reaction of the reagent (1) with the hydroxyl group of (2) followed by intromolecular transfer of methylene. 

Substituted fluorocarbenes have been generated by several methods, but organometallic transfer reagents again are most useful synthetieally [64, 65, 66, 67, 68] (equations 25-27) Diazirines cleanly produce carbenes thermally [69, 71] or... 

Corey s ylide (1), as the methylene transfer reagent, has been utilized in ring expansion of epoxide 75 and arizidine 77 to provide the corresponding oxetane 76 and azetidine 78, respectively. 

Dithiatopazine 73 serves as a sulfur-transfer reagent under thermal conditions. Tlius, heating 73 and diene 130 in toluene at 100°C formed a cyclic disulfide 131 (25%) and a tetrasulfide 132 (28%) with the formation of the alkene 118 (90%). Under similar conditions, the highly strained acetylene 133 was converted to the 1,2-dithiete 134 (65%) and the congested thiophene 135 (12%) (90JA3029). 

Although the base-catalyzed addition of nitroalkanes to electron-deficient olefins has been extensively used in organic synthesis fsee Michael addition Chapter 4, it is only recently that the reaction has been extended to the cyclopropanadon reaction. In 1978, it was reported that the anion of nitromethane reacts with certain highly electron-deficient olefins to produce cycloptopanesingoodyieldrEq. 7.36. More recently, this reaction has been extended to more general cyclopropanadons, as shown in Eqs. 7.37 and 7.38, in which potassittm salts of nitroalkanes are employed in DMSO as alkylidene transfer reagents." ... 

Because anions of nitro compounds are good electron-transfer reagents, they can serve as reducing agents in radical type eliminations of vicinal dinitro compounds. In fact, N- azolyl- sub-... 

It should be emphasized that ionic liquids are simply organic salts that happen to have the characteristic of a low melting point. Many ionic liquids have been widely investigated with regard to applications other than as liquid materials as electrolytes, phase-transfer reagents [12], surfactants [13], and fungicides and biocides [14, 15], for example. 

Racemic 5-methyl-5 -(sodiomethyl)-A-(4-methylphenylsulfonyl)sulfoximine reacts with ketones to give an initial methylene transfer which produces an intermediate epoxide that is ring expanded to the oxctanc56. Application to 4-rerf-butylcyclohexanonc affords a single oxetane in 69% yield. While only achiral alkylidcne transfer reagents were utilized, in principle this reaction is amenable to the asymmetric synthesis of oxetanes. 

Balli and Felder (1978) and Balli and Ritter (1981) showed that diazo transfer can be applied advantageously to the diazotization of sufficiently nucleophilic heteroaromatic compounds such as 5-hydroxy- and 5-amino-3-methyl-l-phenyl-pyrazole if 3-ethyl-2-azido-benzthiazolium tetrafluoroborate (2.50) is used as diazo transfer reagent (for other applications of this diazo transfer reagent see Zollinger, 1995, Secs. 2.6-2.8). The diazonio group is introduced in the 4-position (2.51). 

This statement applies only to the comparison of I with Br-, Cl-, and F. For other electron transfer reagents containing iodine, compare Secs. 10.6 and 10.11. 

Several other electron-transfer reagents have been tested with arenediazonium ions, for example, A-benzyl-l,4-dihydronicotinamide, which is a model for biochemical reductions by NAD(P)H, the reduced form of NADP+ (nicotinamide adenine cfinucleotide phosphate) (Yasui et al., 1984). 

Fig. 8-7. Dependence of the yield in chloro-de-diazoniations on the redox potential of electron transfer reagents (from Galli, 1988 Fc = ferrocene).

Table 10-1. Yield of chlorobenzene in chloro-de-diazoniation of benzenediazonium sulfate as a function of electron transfer reagent and ligand transfer reagent. Experiments 1-5 from Galli, 1981a), experiment 6 from Daasbjerg and Lund, 1992b).

Exp. no. Electron transfer reagent Ligand transfer reagent Yield ArCl (Vo)... 

Cyano-de-diazoniations of the Sandmeyer type have been used for the synthesis of aromatic nitriles for many decades (example Clarke and Reed, 1964), as cyanide ions are comparable to bromide and iodide in many respects. A homolytic cyano-de-diazo-niation that does not use metal ions as reductant or ligand transfer reagent was described by Petrillo et al. (1987). They showed that substituted diazosulfides (XC6H4 — N2 — SC6H5), either isolated or generated in situ from arenediazonium tetrafluoroborates and sodium benzenethiolate, react with tetrabutylammonium cyanide in dimethylsulfoxide under photon stimulation, leading to nitriles (XC6H4CN). The method worked well with eleven benzenediazonium ions substituted in the 3- or 4-position, and was also used for the synthesis of phthalo-, isophthalo-, and tere-... 

A number of approaches have been tried for modified halo-de-diazoniations using l-aryl-3,3-dialkyltriazenes, which form diazonium ions in an acid-catalyzed hydrolysis (see Sec. 13.4). Treatment of such triazenes with trimethylsilyl halides in acetonitrile at 60 °C resulted in the rapid evolution of nitrogen and in the formation of aryl halides (Ku and Barrio, 1981) without an electron transfer reagent or another catalyst. Yields with silyl bromide and with silyl iodide were 60-95%. The authors explain the reaction as shown in (Scheme 10-30). The formation of the intermediate is indicated by higher yields if electron-withdrawing substituents (X = CN, COCH3) are present. In the opinion of the present author, it is likely that the dissociation of this intermediate is not a concerted reaction, but that the dissociation of the A-aryl bond to form an aryl cation is followed by the addition of the halide. The reaction is therefore mechanistically not related to the homolytic halo-de-diazoniations. 

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