Sulfenyl intermediates

Bromide and iodide ions are not only effective as redox catalyst in the indirect electrochemical formation of carbon-hetero atom bonds but also of hetero-hetero atom bonds. Thus, the nitrogen-sulfur bond in sulfenimides (Eq. (53) Table 4, No. 33) and sulfenimines (Eq. (54) Table 4, No. 34) can be generated. The electrogenerated active bromine species forms a positively polarized sulfenyl intermediate from disulfides. 

It is more likely to assume that if sulfonyl chloride is present in flie medium, the quatemization of flie nitrogen in 6 is possible, leading to a -sulfenyl intermediate 12 in the first step of fire reaction. Now, the electrophihcity of the C=N bond is increased and a nucleophilic attack by the SPh group would form fire episulfo-nium species 13 that by ring opening would lead to A -phenylsulfenyl 2,3-bis-sulfide 14. Removal of fire SPh group in 14 during the aqueous workup would yield the final bis-sulfide 7 (Scheme 2.9). 

The 2-thienylthiourea (245) on oxidation with bromine in acetic acid gave the thieno[3,2-djthiazole (247). It has been suggested that the intermediate electrophilic sulfenyl bromide adds to the 2,3-bond of the thiophene ring to form (246) when then loses HBr to give (247) (71AJC1229, 78JHC81). Pyrazolo(3,4- /]thiazoles are formed in a similar fashion (76GEP2429195). 

MO calculations for the gas phase indicate that sulfurane intermediate (17) is more stable than the ion (18) by about 380 kJ moP, which suggests that sulfuranes may be important in the reaction of sulfenyl halides with alkenes in non-polar solvents (77JCS(P2)1019). 

Chlorination of thiiranes in hydroxylic solvents gives /3-chloroethylsulfonyl chlorides due to further oxidation of the intermediate sulfenyl chloride by chlorine or hypochlorous acid (Scheme 40). Polymer is usually obtained also unless the reaction is done in concentrated hydrochloric acid, which causes rapid ring cleavage to 2-chloroethylthiols which are subsequently oxidized to the sulfonyl chlorides. An 85% yield of (37) is obtained in concentrated hydrochloric acid-HCl(g) whereas only a 15% yield is obtained in CCI4-H2O. 

Fluoride ion attacks the sulfur atom in 2,3-diphenylthiirene 1,1-dioxide to give ck-1,2-diphenylethylenesulfonyl fluoride (23%) and diphenylacetylene (35%). Bromide or iodide ion does not react (80JOC2604). Treatment of S-alkylthiirenium salts with chloride ion gives products of carbon attack, but the possibility of sulfur attack followed by addition of the sulfenyl chloride so produced to the alkyne has not been excluded (79MI50600). In fact the methanesulfenyl chloride formed from l-methyl-2,3-di- -butylthiirenium tetrafluoroborate has been trapped by reaction with 2-butyne. A sulfurane intermediate may be indicated by NMR experiments in liquid sulfur dioxide. 

The disulfides are useful intermediates in the preparation of sulfenyl chlorides. ... 

Sulfenamides arc usually oxidized to sulfonamides tns(tnfluorotnetliane-sulfenyl) and bis(tnfluoromethanesulfenyl)arnineare converted to the corresponding sulfonamides by sodium hypochlorite at 20 tor 3 h m 61 and 92% yield, respecbvely [111] Oxidation of pentafluorobenzenesulfendimde by manganese dioxide yields a sulfinamide intermediate that can be trapped [772] (equabon 102)... 

Pieces of various routes to moxalactam have been published from which the following may be assembled as one of the plausible pathways. The benzhydrol ester of 6-aminopenici 11 anic acid ( ) is -chlorinated and treated with base whereupon the intermediate sulfenyl chloride fragments to ). Next, displacement with propargyl alcohol in the presence of zinc chloride gives predominantly the stereochemistry represented by dia-stereoisomer The side chain is protected as the phenyl-... 

From intermediate 12, the path to periplanone B (1) is short but interesting. Enolization of 12 with lithium bis(trimethylsilyl)amide at -78 °C, followed by sulfenylation using Trost s reagent,12 affords a 16 1 mixture of regioisomeric monosulfenylated ketones favoring intermediate 17. The regioselectivity displayed in this reaction is... 

In the reaction of ketones with thionyl chloride the intermediate sulfinyl (or sulfenyl) chloride can cyclize on to an aromatic ring located two carbon atoms away giving benzo[b]thiophenes (48) (Scheme 7).54 Additional... 

What is retained nowadays of the initial mechanism (Scheme 1) is the occurrence of a cationic intermediate. But bromine bridging is not general, and its magnitude depends mainly on the double bond substituents (Ruasse, 1990). For example, when these are strongly electron-donating, i.e. able to stabilize a positive charge better than bromine, / -bromocarbocations are the bromination intermediates. The flexibility of transition state and intermediate stabilization puts bromination between hydration via carbocations and sulfenylation via onium ions. 

Insertion of carbon monoxide into Csp2—Zr bonds occurs readily at ambient temperatures or below to produce a,(5-unsaturated, reactive acyl zirconocene derivatives [27—29]. Early work by Schwartz demonstrated the potential of such intermediates in synthesis [5d], as they are highly susceptible to further conversions to a variety of carbonyl compounds depending upon manipulation. More recently, Huang has shown that HC1 converts 16 to an enal, that addition of a diaryl diselenide leads to selenoesters, and that exposure to a sulfenyl chloride gives thioesters (Scheme 4.11) [27,28]. All are obtained with (F)-stereochemistry, indicative of CO insertion with the expected retention of alkene geometry. 

However, a few thiols (cysteine, N-acetylcysteine and thiosalicylic acid) also react with organic nitrates to release NO by another process that is difficult to discern. It could be that the nitrite reacts with a thiol to give an S-nitrosothiol, a ready source of NO, but nitrosation is unlikely to occur at biological pHs. Another possible route to NO involves formation of a thionitrate by trans-esterification [59] (Eq. (12)). This species could then decompose to give NO via an intermediate sulfenyl compound [60] (Eq. (13)). 

In earlier days it was fairly common to suggest that sulfenium ions, RS+, were involved as intermediates in a number of these substitutions, particularly those in which sulfenyl halides RSX reacted with very weak nucleophiles, or those where electrophilic catalysis of the substitution was observed (Parker and Kharasch, 1959). However, it has since become evident (Owsley and Helmkamp, 1967 Helmkamp et al., 1968 Capozzi et al., 1975) that sulfenium ions are almost impossible to generate as intermediates. For example, Capozzi et al., (1975) showed that although treatment of a sulfenyl chloride RSC1 with the powerful Lewis acid antimony pentafluoride led to the complete conversion of the sulfenyl chloride to a cation, what was formed was, not the sulfenium ion RS+, but rather the cation [59] in reaction (172). These results, and others... 

Such bimolecular substitutions at a sulfenyl sulfur, just as was true for analogous substitutions at sulfinyl sulfur, can in principle take place either by a mechanism in which bond making and bond breaking are concerted (173a), or alternatively, by one (173b) where bond making precedes bond breaking and an intermediate [60] is present on the reaction co-ordinate. 

Douglass, 1959) to involve an initial nucleophilic attack by the thiolsulfonate on the sulfenyl chloride to give the ion pair intermediate [72] which then yields the products by attack of the chloride ion on the sulfonyl group (184). 

The timing of bond making and bond breaking in direct substitutions at a sulfonyl group presents the same problems as it did in substitutions at sulfinyl OS=0) and sulfenyl ( S) sulfur. Are such reactions concerted (196a) or are they stepwise (196b) with an intermediate [77] present on the reaction... 

The formation of the bridged intermediate has been represented as an SN2-like displacement of the leaving group from the sulfenyl sulphur of 85116, or alternatively, as reported in equation 90 in agreement with the addition of other electrophiles to alkenes, it has been proposed that the reaction involves the initial formation of jr-complex 86 in a rapid equilibrium with the reagents76. 

Simple 1,2-additions to this compound have been observed123131132 also in other sulfenylation reactions, and in other electrophilic additions involving strongly bridged intermediates. Although these results have been interpreted as evidence that additions of sulfenyl halides to symmetrical alkenes do not involve open carbenium ions before the product-determining step, the different behavior observed in the case of 49 suggests123 that close proximity is necessary to have transannular participation of 7r-bonds, at least in additions of sulfenyl derivatives and of some other electrophiles carried out in the presence of efficient nucleophiles. 

Areneselenenyl halides react with double bonds similarly to sulfenyl derivatives 1,2-additions are generally anti stereospecific, in agreement with the involvement of a bridged intermediate [episelenurane (a) and/or seleniranium ions (b)], prior to the product-forming step. 

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