Sulphinates hydrolysis

Phenylsulphine prepared in situ from phenylmethanesulphinyl chloride and triethyl-amine reacted with 1 -morpholinocyclohexene to form the addition product 169 having the enamine structure218. A similar experiment with phenylsulphine and 2-pyrrolidinocyclo-hexene gave only 2-phenylmethanesulphinyl cyclohexanone 170. The latter is most probably formed by hydrolysis of the corresponding enamine sulphoxide upon isolation. The reaction of sulphines with enamines is apparently a stepwise process involving the transient formation of the dipolar intermediate 171 which is stabilized by proton transfer, giving the enamine sulphoxide. 

Optically active sulphoxides 311 and 312 have been prepared stereospecifically either by hydrolysis of the optically active sulphonium salt 313 or by the reaction of p-tolyl magnesium bromide with optically active sulphinate 314, respectively377 (equations 167 and 168). 

Sulphimides, photolysis of 878, 879 Sulphimines, hydrolysis of 279 Sulphinamides 70, 71 Sulphinate nucleophiles, S-substitution of 172-189... 

In recent years the importance of entropy contributions to the increased rates of reaction of five-membered cyclic esters has been recognised. Thus the high reactivity of the oxaphospholan ring has been shown to arise from a combination of both enthalpy and entropy strain153. On the other hand, entropy strain is the main cause of kinetic acceleration in the alkaline hydrolysis of cyclic sulphite and sulphinate esters154,155. 

The oxidation of thiols is accelerated remarkably by traces of catalyst and this reaction forms the basis of petroleum sweetening processes. Although transition metal ions are the most effective catalysts, any additive capable of catalysing electron transfer accelerates the reaction. Nitrobenzene in dimethylformamide/potassium hydroxide [118], 2-nitro-thiophene, tetracyanoethylene, and 4-nitropyridine-N-oxide [118] are all good catalysts for the oxidation of 1-butane thiol. The alkaline hydrolysis of disulphides containing aryl, carbonyl, and alpha unsaturated groups also results in catalysis, apparently due to the setting up of a sulphinate—sulphenate redox cycle [119—121]. 

Disproportionation of sulphenic adds has also been suggested as a possible route for the formation of these compounds (equation 24). The hydrolysis of sulphenyl halides under not carefully controlled conditions and particularly in concentrated solutions lead to disulphides and thiolsulphonates because of the easy disproportionation of thiol-sulphinates (equation 25). 

Careful hydrolysis of alkyl or aryl sulphur trihalides, in particular trichlorides, yields either sulphinic acid or sulphinyl halide . The latter is obtained in good yields by reacting the trihalide with the stoichiometric amount of acetic acid (equation 19). 

There is little effect of micelles upon the rate of an intramolecular nucleophilic reaction. Micelles of hexadecyltrimethylammonium bromide catalyse, by factors of 10 —10, the arenesulphinate anion-induced hydrolysis of 4-tolylsulphonyl-methyl perchlorate. There is no relationship between the rate acceleration and hydro-phobicity of the sulphinate anion and catalysis is attributed to the concentration of the reactants in the micellar phase.The rate constants for the reaction of nucleophiles with carbonium ions and those for the addition of cyanide ion to the A -alkylpyridinium ions are similar in the micellar and aqueous phases, and the rate enhancement is due to the concentration of reactants in the micellar pseudophase. Similarly, although micellar catalysed dephosphorylation by nucleophiles may show rate enhancements of up to 4 x 10 -fold, the second-order rate constants may be slightly smaller in the micellar pseudophase lowing to its lower polarity. However, the reaction of fluoride ion with 4-nitrophenyldiphenyl phosphate is very rapid in micelles of cetyltrimethylammonium fluoride, but the rate constant continues to increase when the substrate is fully bound with increasing cetyltrimethylammonium fluoride or sodium fluoride. The failure of the micellar pseudophase model is also apparent in the reaction of hydroxide ion with 2,4-dinitrochlorobenzene. It is suggested that reaction occurs between reactants in the aqueous and micellar pseudophases and also between hydroxide ion in water and substrate in the micelle. ... 

Metal oxides have been employed to catalyse the acylation of aromatics, leading to dimethylbenzophenones and 4-substituted benzophenones. The reaction of t-butylbenzene with benzoyl chloride in the presence of small amounts of ferric oxide leads to 4-t-butylbenzophenone. Substituted benzophenones have also been obtained by hydrolysis of the dilithium salts (68) formed by the reaction of lithium carboxylates with organolithium derivatives, and benzo-phenone-2 -methoxy-2-sulphinic acids (69) have been successfully prepared by displacement of the sulphone linkage in thioxanthen-9-one 10,10-dioxides (70)... 

Oxidation of thioketones with peroxy-acids gives sulphines, e.g. (38) in one example, the syn- and anti-vsovast could be separated. In contrast, di-t-butyl selenoketone yields di-t-butyl ketone and selenium. The hydrolysis of mono-thioacetylacetone and monothiobenzoylacetone in acidic solution leads to the... 

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