27872-70-4

Upstream product

• 17042-24-9 2-mercapto-pentan-3-one 
• 100-34-5 benzene diazonium chloride 
• 931-59-9 benzenesulfenyl chloride 
• 108-98-5 thiophenol 
• 96-22-0 pentan-3-one 
• 4187-86-4 pent-1-yn-3-ol 
• 17042-21-6 2-chloro-3-pentanone 
• 13307-56-7 1,1-bis(phenylthio)ethane 
• 815-52-1 2-bromopentan-3-one 
• 51425-53-7 (E)-3-[(trimethylsilyl)oxy]pent-2-ene 
• 66303-47-7 (2-Chloro-2-ethoxy-ethylsulfanyl)-benzene 
• 71221-33-5 2,2-bis(phenylthio)pentan-3-ol 
• 52322-54-0 2-(phenylthio)benzo[d]isothiazol-3(2H)-one 1,1-dioxide 
• 51425-54-8 (Z)-3-trimethylsiloxy-2-pentene 

Downstream Products

• 96-22-0 pentan-3-one 
• 882-33-7 diphenyldisulfane 
• 113503-13-2 2-(phenylmethylsulfonio)-3-pentanone triflate 
• 1896-62-4 (E)-benzalacetone 
• 55834-35-0 4-methyl-4-(phenylthio)hept-6-en-3-one 
• 55834-34-9 4-methyl-4-phenylsulfanyl-octan-3-one 

Relevant academic research and scientific papers

Synthesis and reactivity of α-sulfenyl-β-chloroenones, including oxidation and Stille cross-coupling to form chalcone derivatives

The synthesis of a range of novel α-sulfenyl-β-chloroenones from the corresponding α-sulfenylketones, via a NCS mediated chlorination cascade, is described. The scope of the reaction has been investigated and compounds bearing alkyl- and arylthio substituents have been synthesised. In most instances, the Z α-sulfenyl-β-chloroenones were formed as the major products, while variation of the substituent at the β-carbon position led to an alteration in stereoselectivity. Stille cross-coupling with the Z α-sulfenyl-β-chloroenones led to selective formation of Z sulfenyl chalcones, while the E α-sulfenyl-β-chloroenones did not react under the same conditions. Oxidation of the Z α-sulfenyl-β-chloroenones was followed by isomerisation, leading to the E α-sulfinyl-β-chloroenones. Stille cross-coupling with the E α-sulfinyl-β-chloroenones produced the E sulfinyl chalcones. Either the E or Z sulfinyl chalcones can be obtained by altering the sequence of oxidation and Stille cross-coupling.

Catalytic, Enantioselective Sulfenylation of Ketone-Derived Enoxysilanes

A catalytic, enantioselective, Lewis base-catalyzed α-sulfenylation of silyl enol ethers has been developed. To avoid acidic hydrolysis of the silyl enol ether substrates, a sulfenylating agent that did not require additional Br?nsted acid activation, namely N-phenylthiosaccharin, was developed. Three classes of Lewis bases - tertiary amines, sulfides, and selenophosphoramides - were identified as active catalysts for the α-sulfenylation reaction. Among a wide variety of chiral Lewis bases in all three classes, only chiral selenophosphoramides afforded α-phenylthio ketones in generally high yield and with good enantioselectivity. The selectivity of the reaction does not depend on the size of the silyl group but is highly sensitive to the double bond geometry and the bulk of the substituents on the double bond. The most selective substrates are those containing a geminal bulky substituent on the enoxysilane. Computational analysis revealed that the enantioselectivity arises from an intriguing interplay among sterically guided approach, distortion energy, and orbital interactions.

α-Organylchalcogenation of aldehydes and ketones with diorganyl dichalcogenides promoted by K3PO4

A new catalytic method for direct α-organylchalcogenation of aldehydes and ketones has been developed. When various aldehydes and ketones were allowed to react with diorganyl dichalcogenides in the presence of K 3PO4, under mild reac

Tandem Pd/Au-catalyzed route to α-sulfenylated carbonyl compounds from terminal propargylic alcohols and thiols

An efficient and highly atom-economical tandem Pd/Au-catalyzed route to α-sulfenylated carbonyl compounds from terminal propargylic alcohols and thiols has been developed. This one-step procedure has a wide substrate scope with respect to substituents at

N-Chlorosuccinimide as a versatile reagent for the sulfenylation of ketones: a facile synthesis of α-ketothioethers

The sulfenylation of ketones having α-hydrogens has been achieved using N-chlorosuccinimide (NCS) under mild reaction conditions to produce α-ketothioethers in excellent yields with high selectivity. The use of NCS makes this method quite simple, convenient and practical.

ALKENE CARBOSULPHENYLATION AND CARBOSELENYLATION: THE USE OF ALLYLTRIMETHYLSILANE AND O-SILYLATED ENOLATES.

Allyltrimethylsilane, as well as O-silylated enolates, can be alkylated by the PhSCl adducts of alkenes and vinyl ethers (1, X=SPh); the PhSeCl analogues (1, X=SePh), however, are less useful for alkylation purposes due to competing nucleophilic attack at selenium.