Sulfonate complexes, from oxidation

The kinetics of chromium(l 11 )-catalyscd oxidation of fonnic acid by Ce(TV) in aqueous H2SO4 can be rationalized in terms of initial formation of an outer-sphere complex involving oxidant, catalyst, and substrate (S), Ce(TV)(S)Cr(III), followed by an inner-sphere complex Ce(III)(S)Cr(IV). It is proposed that electron transfer occurs within this complex from substrate to Cr(TV) (with elimination of H+) followed by fast reaction to give CO2 (again with elimination of H+).54 In contrast, there was no kinetic evidence for the accumulation of a corresponding inner-sphere intermediate in the osmium(VIII)-catalysed Ce(TV) oxidation of DMSO to dimethyl sulfone here, the observed rate law was rationalized in terms of rate-determining bimolecular electron transfer from DMSO to Os(VHI) in an outer-sphere step.55 The kinetics of oxidation of 2-hydroxy-l-naphthalidene anil by cerium(IV) in aqueous sulfuric acid have been... 

Most recently, they have developed a cell configuration for the study of modified electrodes that employs, as a working electrode, colloidal graphite deposited onto kapton tape (typical window material). Such an arrangement minimizes attenuation due to the electrolyte solution. They coated the working electrode with a thin film of Nafion (a perfluoro sulfonate ionomer from E. I. DuPont de Nemours, Inc.) and incorporated [Cu(2,9-dimethy-1,10-phenanthroline)2] by ion exchange. They were able to obtain the EXAFS spectra around the copper K edge for the complex in both the Cu(I) and Cu(II) oxidation states. 

Uemura et al. found that the combination Ti(OPr%/binaphthol/water in ratio 1 2 >10 acts as a catalyst for oxidation of aryl methyl sulfides into the corresponding sulfoxides by Bu OOH (see also Section 1.4.1) [159]. A mechanistic study showed that the titanium complex was a sulfoxidation catalyst (initial ee -50%) as well as a catalyst for the overoxidation into sulfones, with an enhancement of the ee of the residual sulfoxides (because the minor sulfoxide enantiomer is preferentially oxidized). In a subsequent paper, the authors reported the kinetic resolution of racemic aryl methyl sulfoxides by the same catalyst [160]. A stereoselectivity factor s of 2.6 was calculated for the kinetic resolution of racemic methyl p-tolyl sulfoxide. For example, methyl p-tolyl sulfoxide (<99% ee) could be recovered from oxidation at about 75% conversion. Using partially resolved l,l -binaphthol, a positive nonlinear effect was established. 

The synthetic sequence involving formation of a thioether, oxidation to the corresponding sulfone and the RBR need not be performed consecutively, although it almost invariably is when applied to the synthesis of complex targets. An example in which divorcing the sulfone preparation from the RBR was actually beneficial to the synthetic strategy is seen in the total synthesis of the resorcylic acid macrolactone (RAL) aigialomycin D by Harvey and coworkers. ... 

As exemplified in the following cases, this addition reaction has often been used as the first step in the preparation of vinyl sulfones. The adduct must therefore undergo a subsequent elimination reaction. A base is needed to perform dehydrohalogenation. The selenides resulting from the addition of selenosul-fonates can be eliminated very smoothly through oxidation. Thus, Yus and co-workers [104] have based a very simple method for the preparation of j9-sulfonyl-a,j9-unsaturated compounds on the addition of tosyl iodide to Michael acceptors (equation (50)) whereas Barton et al. [105] have shown that the addition of phenylseienotosylate to electron-rich olefins, catalyzed by Ru(II) complexes, is efficient (equation (51)). An alternative approach is the Ce(IV)-mediated addition of arylsulfinates to electron-rich olefins which proceeded directly to the olefinic product resulting from oxidative elimination of the intermediate alkyl radical (equation (52)) [106]. 

Solid Superacids. Most large-scale petrochemical and chemical industrial processes ate preferably done, whenever possible, over soHd catalysts. SoHd acid systems have been developed with considerably higher acidity than those of acidic oxides. Graphite-intercalated AlCl is an effective sohd Friedel-Crafts catalyst but loses catalytic activity because of partial hydrolysis and leaching of the Lewis acid halide from the graphite. Aluminum chloride can also be complexed to sulfonate polystyrene resins but again the stabiUty of the catalyst is limited. 

Photooxidafions are also iudustriaHy significant. A widely used treatment for removal of thiols from petroleum distillates is air iu the presence of sulfonated phthalocyanines (cobalt or vanadium complexes). Studies of this photoreaction (53) with the analogous ziuc phthalocyanine show a facile photooxidation of thiols, and the rate is enhanced further by cationic surfactants. For the perfume iudustry, rose oxide is produced iu low toimage quantifies by singlet oxygen oxidation of citroneUol (54). Rose bengal is the photosensitizer. 

The H NMR spectrum of thiirane 1-oxide is complex (AA BB ) at 60 MHz 24 lines are cfbserved consisting of two sets of 12 centered about a midpoint. The H NMR chemical shift in thiirane 1,1-dioxide is fairly sensitive to solvent variations partly because of the high dipole moment (4.4 D) of the sulfone. The benzene-induced shift, A5 (CeDe-CCLt), is large (-1.04 p.p.m.), as expected from the presence of a sulfone group. Oxygen-17 chemical shifts for thiirane 1-oxide and thiirane 1,1-oxide are -71 and +111 p.p.m. respectively, relative to H2O. 

The major problem of these diazotizations is oxidation of the initial aminophenols by nitrous acid to the corresponding quinones. Easily oxidized amines, in particular aminonaphthols, are therefore commonly diazotized in a weakly acidic medium (pH 3, so-called neutral diazotization) or in the presence of zinc or copper salts. This process, which is due to Sandmeyer, is important in the manufacture of diazo components for metal complex dyes, in particular those derived from l-amino-2-naphthol-4-sulfonic acid. Kozlov and Volodarskii (1969) measured the rates of diazotization of l-amino-2-naphthol-4-sulfonic acid in the presence of one equivalent of 13 different sulfates, chlorides, and nitrates of di- and trivalent metal ions (Cu2+, Sn2+, Zn2+, Mg2+, Fe2 +, Fe3+, Al3+, etc.). The rates are first-order with respect to the added salts. The highest rate is that in the presence of Cu2+. The anions also have a catalytic effect (CuCl2 > Cu(N03)2 > CuS04). The mechanistic basis of this metal ion catalysis is not yet clear. 

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