Sulfenamides

Studies on benzothiazoles indicate that sulfenamide formation probably occurs via the mechanism given for the formation of 132 (Scheme 67)... 

A)Ai-dicyclohexyl-2-benzotliiazolesulfenamide (42) [4979-32-2], The cyclohexylamine derivative is preferred over /n/ butylamine [75-64-9] and morpholine sulfenamide analogues because of lower amine volatility and less nitrosamine risk respectively. 

Sulfenamides. Sulfenamides (4) are often produced by oxidising an equimolar mixture of MBT and an aliphatic amine. Alternatively, the /V-ch1oroamine can react with the sodium salt of MBT. One sulfenamide, OTOS (S), uses a thiocarbamyl functionaUty in place of the ben2othia2ole group. 

Guanidines. Guanidines (10) were one of the first aniline derivatives used as accelerators. They are formed by reaction of two moles of an aromatic amine with one mole of cyanogen chloride. Diphenylguanidine (DPG) has enjoyed a resurgence ia demand as an activator for sulfenamides and a co-accelerator ia tire tread compounds which employ siUca fillers for low rolling resistance. Guanidines alone show too Htde activity to be extensively used as primary accelerators. There were no U.S. producers as of mid-1996. 

In the absence of zinc oxide, cross-linking proceeds through an accelerator polysulfide. With TBSI (14) and other sulfenamides, the accelerator decomposes upon heating during the induction period (before cross-linking) as shown in Figure 2 (13). 

It is common practice in the mbber industry for a compounder to use combinations of several accelerators in developing a cure system. Typically these cure systems are comprised of a primary accelerator and one or more secondary types. Primary accelerators are generally the thiazole and sulfenamide classes the secondary types (kickers) are the thiurams, dithiocarbamates, guanidines, and to a much lesser extent, certain amines and the dialkylphosphorodithioates (20). 

Fig. 5. Cure characteristics of accelerators A, thiuram B, dithiocarbamate C, sulfenamide D, thiazole and E, guanidine. The induction period represents...

As a general rule the sulfenamides exhibit faster cure rate than the thiazoles. If secondary accelerators are used, dithiocarbamates are scorchiest and give the fastest cure followed by the thiurams, then the guanidines. Figure 6 summarizes these comparisons to show a series of natural mbber (NR) recipes using either a thiazole (MBTS) or sulfenamide (TBBS) primary accelerator in combination with the various secondary accelerators (21). In this study, the initial primary accelerator levels were selected to produce nearly equivalent modulus or state of cure in the NR. 

Sulfenamide accelerators generally requite less fatty acid because they release an amine during the vulcanization process which acts to solubilize the zinc. Guanidines and similar amine accelerators also serve to both activate and accelerate vulcanization. 

Retarders. The purpose of vulcanization retarders is to delay the initial onset of cure in order to guarantee sufficient time to process the unvulcanized mbber. Three main classes of materials are used commercially, including organic acids and anhydrides, cyclohexylthiophthalimide (Santogard PVI or CTP), and a sulfenamide material (Vulkalent E). 

The thiophthalimide (CTP) and sulfenamide classes of retarders differ from the organic acid types by thek abiUty to retard scorch (onset of vulcanization) without significantly affecting cure rate or performance properties. Much has been pubUshed on the mechanism of CTP retardation. It functions particularly well with sulfenamide-accelerated diene polymers, typically those used in the the industry. During the initial stages of vulcanization, sulfenamides decompose to form mercaptobenzothiazole (MBT) and an amine. The MBT formed reacts with additional sulfenamide to complete the vulcanization process. If the MBT initially formed is removed as soon as it forms, vulcanization does not occur. It is the role of CTP to remove MBT as it forms. The retardation effect is linear with CTP concentration and allows for excellent control of scorch behavior. 

Another commercially available retarder for sulfur vulcanization is based on an aromatic sulfenamide. Like CTP, this product is most effective ki sulfenamide cure systems, but it also works well ki thiazole systems. Performance properties are generally not affected except for a slight modulus kicrease. In some cases this feature allows for the use of lower levels of accelerator to achieve the desked modulus with the added potential benefits of further scorch delay and lower cost cure system (23). 

Metal Ion-Promoted Reactions of Thiols. Metal ion-promoted reactions of thiols have been reviewed (53). The bulk of the coverage concerns metal ion promoted aspects of sulfur chemistry. The main topics of interest are the formation of sulfenamides, sulfides, and disulfides using metal-mediated reactions. 

In Scheme 36 the preparation of a 6-suIfeniminopenicillanate was shown. This could be converted directly to the 6a-methoxypenicillanate as shown in Scheme 44. Alternately, the 6-sulfenimino derivative may be generated from the 6/3-sulfenamide by Mn02 oxidation, followed by introduction of the 6a-methoxy group with LiOMe (79CPB2718). 

Six categories of 7V-hetero atom derivatives are considered N-M (M = boron, copper), N-N (e.g., N-nitro, A-nitroso), N-oxides (used to protect teriary amines), N-P (e.g., phosphinamides, phosphonamides), N-SiR3 (R = CH3), and N-S (e.g., sulfonamides, sulfenamides). 

Sulfenamides, R2NSR, prepared from an amine and a sulfenyl halide, " are readily cleaved by acid hydrolysis and have been used in syntheses of peptides, penicillins, and nucleosides. They are also cleaved by nucleophiles, and by Raney nickel desulfurization. ... 

This sulfenamide, prepared from an amino acid, the sulfenyl chloride, and sodium bicarbonate, is cleaved by acid hydrolysis (HOAc/dioxane, 22°, 30 min, 95% yield). 

Af,Af-dicyclohexyl-benzothiazole-sulfenamide (DCBS), cobalt naphthenate, and diaryl-p-diphenylene-amine (each 1 phr). 

After reaction for 15 min, the band near 3295 cm (not shown in Fig. 13) decreased significantly in intensity, indicating that the mono-substituted acetylene groups were reacting. New bands also appeared near 1539 and 1512 cm . After reaction for 30 min, several additional bands appeared near 1011, 1030, 1085, 1232, 1320, 1430, and 1515 cm. The bands near 1011, 1030, 1085, 1232, 1320, and 1430 cm were clearly related to the benzothiazole sulfenamide fragment of DCBS while the band near 1539 cm was related to zinc stearate. 

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)... 

The solvated sulfenamides [Li2( BuNSC6H4Me-4)2(THF)n] (n = 2,4) have dimeric structures with a central Li2N2 ring. The coordination mode is determined by the extent of solvation of the Li" ions monosolvation allows for rj -N,S coordination whereas disolvation restricts the coordination mode to // -M Variable temperature NMR studies indicated that a dynamic exchange between these two structural types occurs in THF solution (Scheme 10.10). The dihapto coordination mode is observed exclusively in transition-metal complexes and the... 

Benzenesulfenamide and a number of substituted benzenesulfenamides (compounds B, C, and D) have been prepared to protect the 7-amino group in cephalosporins. They are cleaved by sodium iodide (CH3OH, CH2CI2, AcOH, 0°, 20 min, 53% yield from sulfenamide B)."... 

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