Indium‐Catalyzed Deoxygenation of Sulfoxides with Hydrosilanes

Photocatalytic Reduction of Allyl Sulfones to Sulfides via Phosphine-Mediated Deoxygenation

PPh3 is shown to be an effective reagent for the deoxygenative reduction of allyl sulfones to sulfides under photocatalytic conditions. Cross-over experiment suggests that the reaction proceeds in a sequential approach involving radical fragmentation and deoxygenation of sulfonyl radical to a thiyl radical, which recombines with the terminal alkene. This mild protocol exhibits broad functional group tolerance, and its applications are explored through scale-up reactions.

Samarium(II) Diiodide-Mediated Deoxygenation of Sulfoxides

Samarium diiodide-mediated deoxygenative activation of sulfoxides by selective S-O cleavage to construct thioethers under mild room temperature conditions has been achieved. A broad variety of sulfoxides, including aryl-aryl, aryl-alkyl, aryl-alkenyl, and alkyl-alkyl sulfoxides, can be readily converted to the corresponding thioethers using the highly chemoselective, operationally simple, and benign SmI2/Et3N reagent system. Extensive studies on the effect of additives indicate that typical samarium(II) iodide additives, such as water, alcohols, HMPA or nickel, have a negative impact on this valuable deoxygenation, while triethylamine promotes the deoxygenation in a versatile manner to afford synthetically useful thioether products.

Selective Synthesis of Vinyl Sulfides or 2-Methyl Benzothiazoles from Disulfides and CaC2 Mediated by a Trisulfur Radical Anion

In this report, we have established a novel and efficient method for selectively synthesizing either vinyl sulfides or 2-methylbenzothiazoles from the reaction of CaC2 and disulfides. The selective synthesis of these two distinct products can be controlled by simply adjusting the amount of K2S. The underlying reaction mechanism has been thoroughly investigated through control experiments, HRMS, and FTIR, which collectively support the pivotal role of a trisulfur radical anion. This radical species, generated in situ from K2S, is essential for the homolytic cleavage of the S-S bonds in a catalytic manner. Additionally, the trisulfur radical anion also acts as an effective mediator for activating the vinyl group of 2-aminophenyl vinyl sulfides, facilitating the crucial intramolecular cyclization required to produce 2-methylbenzothiazoles. Moreover, CaC2 not only serves as an acetylene source but also creates the basic conditions essential for the selective formation of vinyl sulfides. This methodology demonstrates broad substrate compatibility and excellent functional group tolerance, significantly enhancing its practical utility in diverse synthetic applications.

2,5-[C4+C2] Ringtransformation of Pyrylium Salts with α-Sulfinylacetaldehydes

A rapid synthesis of chiral sulfoxide-functionalized meta-terphenyl derivatives by a 2,5-[C4+C2] ring transformation reaction of pyrylium salts with in situ generated enantiomerically pure α-sulfinylacetaldehydes is described in this paper. This synthetic method demonstrates, for the first time, the use of α-sulfinylacetaldehydes in a reaction sequence initiated by the nucleophilic attack of pyrylium salts by α-sulfinylcarbanions to generate chiral aromatic systems. The method presented shows a broad applicability starting with various methyl sulfoxides and a number of functionalized pyrylium salts, furnishing meta-terphenyls with complex substitution patterns from readily accessible starting compounds.

DBDMH-Promoted Methylthiolation in DMSO: A Metal-Free Protocol to Methyl Sulfur Compounds with Multifunctional Groups

Organic thioethers play an important role in the discovery of drugs and natural products. However, the green synthesis of organic sulfide compounds remains a challenging task. The convenient and efficient synthesis of 5-alkoxy-3-halo-4-methylthio-2(5H)-furanones from DMSO is performed via the mediation of 1,3-dibromo-5,5-dimethylhydantoin (DBDMH), affording a facile route for the sulfur-functionalization of 3,4-dihalo-2(5H)-furanones under transition metal-free conditions. This new approach has demonstrated the functionalization of non-aromatic Csp2-X-type halides with unique structures containing C-X, C-O, C=O and C=C bonds. Compared with traditional synthesis methods using transition metal catalysts with ligands, this reaction has many advantages, such as the lower temperature, the shorter reaction time, the wide substrate range and good functional group tolerance. Notably, DMSO plays multiple roles, and is simultaneously used as an odorless methylthiolating reagent and safe solvent.