Halogens sulfoxides

Thiols are powerful reducing agents, which may be oxidized by O2, peroxides, halogens, sulfoxides, or metal ions in high oxidation states [FeCb, Pb(02CMe)4] usually disulfanes are formed in these reactions. Oxidation of thiols by sulfur(IV) or sulfur(Vl) compounds often results in mixtures of polysulfanes. 

Sulfoxides Z =S=0 1075-1040 (vs) 730-690 (var) 395-360 (var) Halogen or oxygen atom bonded to sulfur increases the frequency. 

I itro-DisplacementPolymerization. The facile nucleophilic displacement of a nitro group on a phthalimide by an oxyanion has been used to prepare polyetherimides by heating bisphenoxides with bisnitrophthalimides (91). For example with 4,4 -dinitro monomers, a polymer with the Ultem backbone is prepared as follows (92). Because of the high reactivity of the nitro phthalimides, the polymerkation can be carried out at temperatures below 75°C. Relative reactivities are nitro compounds over halogens, Ai-aryl imides over A/-alkyl imides, and 3-substituents over 4-substituents. Solvents are usually dipolar aprotic Hquids such as dimethyl sulfoxide, and sometimes an aromatic Hquid is used, in addition. 

The preparation of isothiazolidin-3-one 5-oxide and 5,5-dioxide derivatives of azetidin-3-ones was described (99EUP100069), starting from penicillanic acid sulfoxide amides in the presence of halogenating agents in anhydrous inert solvents or even without them. Through rearrangement and oxidation with conventional methods, compounds 73 could be obtained. For some derivatives the usefulness, as intermediates for the preparation of novel p-lactam analogs or active substances in formulations for antimicrobial therapy, is claimed. 

Treatment of pyridyl carbinol 51 with thionyl chloride leads to the corresponding chloride (52), Treatment of that intermediate with 5-methoxy-2-mercaptobenzimidazole (53), obtained from reaction of 4-methoxy-q-phenylenediamine with potassium ethylxanthate leads to displacement of halogen and formation of the sulfide (54). Finally, oxidation with 3-chloroperbenzoic acid produces the sulfoxide omeprazole (55) fl7]. 

Bordwell and coworkers63 87 have studied the reaction of 9-fluorenyl carbanions (9-RFP) with a series of electron acceptors and in particular a-halosulfones and sulfoxides, in dimethyl sulfoxide solution. The overall reaction is characterized by the formation of the 9,9 -bis-fluorenyl derivative and the reduction of the halogenated acceptor. A family of 9-substituted fluorenyl carbanions covering a basicity range of 9.1 pKa units was used and... 

Introduction of the phenylthio group onto the 5-carbon atom of alcohols can have valuable synthetic applications. 5-Phenylthio alcohols can be oxidized to the corresponding 5-sulfoxides and sulfones (with their versatile reactivities) or they can be deprotonated by strong base converting the 5-carbon atom to a nucleophilic species. Conversion of 5-phenylthio alcohols to the corresponding 5-carbonyl compounds can be achieved via halogenation followed by subsequent hydrolysis. In this way an inversion of the reactivity of the 5-carbon atom may be accomplished and it can react as an electron acceptor. 

Oxidation of thiophene with Fenton-like reagents produces 2-hydroxythiophene of which the 2(570 One isomer is the most stable (Eq. 1) <96JCR(S)242>. In contrast, methyltrioxorhenium (Vn) catalyzed hydrogen peroxide oxidation of thiophene and its derivatives forms first the sulfoxide and ultimately the sulfone derivatives <96107211>. Anodic oxidation of aminated dibenzothiophene produces stable radical cation salts <96BSF597>. Reduction of dihalothiophene at carbon cathodes produces the first example of an electrochemical halogen dance reaction (Eq. 2) <96JOC8074>. 

A convenient modification of the Gassman oxindole synthesis was reported using ethyl (methylsulfinyl)acetate (101) activated by oxalyl chloride to generate the same chlorosulfonium salt 102 normally generated from ethyl (methylthio)acetate 100 and elemental chlorine <96TL4631>. Thus, treatment of the sulfoxide 101 with oxalyl chloride, followed by the addition of the desired aniline, triethylamine, and finally acid cyclization of 103 affords the oxindoles 104. This procedure is particularly convenient for reactions carried out on smaller scales and for anilines that ate susceptible to electrophiUc halogenation. 

Halogenation of 106 with triphenylphosphine, iodine, and imidazole provided the iodo derivative 109. On treatment with lithium aluminum hydride, 109 was converted into two endocyclic alkenes, 110 and di-O-isopro-pylidenecyclohexanetetrol, in the ratio of 2 1. Oxidation of 110 with dimethyl sulfoxide - oxalyl chloride afforded the enone 111.1,4-Addition of ethyl 2-lithio-l,3-dithiane-2-carboxylate provided compound 112. Reduction of 112 with lithium aluminum hydride, and shortening of the side-chain, gave compound 113, which was converted into 114 by deprotection. ... 

The comparison of the results of a-halogenation with those of a-methylation of six-membered ring sulfoxides reveals that similar factors are operative and determine the stereochemical outcomes in both cases. 

An explosion was experienced dining work up of an epoxide opening reaction involving acidified sodium azide in a dichloromethane/dimethyl sulfoxide solvent. The author ascribes this to diazidomethane formation from dichloromethane [1]. A second report of an analoguous accident, also attributed to diazidomethane, almost certainly involved hydrogen azide for the cold traps of a vacuum pump on a rotary evaporator were involved this implies an explosive more volatile than dichloromethane. It is recommended that halogenated solvents be not used for azide reactions [2]. 

The oxidation of thioamides 63 with a wide variety of oxidizing agents is a well-employed method for the synthesis of 3,5-disubstituted-l,2,4-thiadiazoles 64 <1982AHC285>. However, this method is limited mainly to arylthioamides. The most common oxidizing agents tend to be halogens, hydrogen peroxide, dimethyl sulfoxide (DMSO), and nitrous acid. Yields from these reactions are variable and depend on the thioamide, oxidant, and conditions used (Equation 19). By-products such as nitriles and isothiocyanates are usually formed. 

Platinum(IV) species have been conveniently synthesized from the reaction between halogens and platinum(II) sulfoxide complexes (6). Studies of the redox properties of such complexes show that they have a particularly high redox potential. Thus, the redox potentials for Eq. (38) are 0.872 V (R = Me) and 0.877 V (R = Et), measured at 25°C (I = 0.1 M). For comparison, the equivalent redox potential for [Pt(pyri-dine)Cls]- is 0.809 V (349). 

Since the solvent properties of dimethyl sulfoxide are widely different from those of hydrocarbons and halogenated hydrocarbons, it may be difficult to compare the kinetic and thermodynamic data for the C02H group (Table 16) directly with others. However, heating the carboxylic acid (68, X = OH) in toluene affords the sp isomer almost exclusively. Probably, the observed results with the carboxylic acid derive from difficulty in the formation of a hydrogen bond owing to a steric effect, in addition to the nonplanar conformation of the carboxyl group relative to the naphthalene. 

Chiral alcohols have also been used to induce optical activity in sulfoxides during halogenation of sulfides. Thus, Johnson (58) found... 

The formation of halogenosulfonium salts is considered to be the first step in the -halogenation of sulfoxides. The mechanism and stereochemistry of a-halogenation of sulfoxides are discussed in detail by Montanari in his recent review paper (9). 

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