3111-54-4

Usage

Uses

Used in Organic Synthesis:
2-Phenylthiopyridine is used as a building block in organic synthesis for its ability to participate in various organic reactions, such as C-H activation and cross-coupling reactions. Its unique structure allows for the formation of new chemical entities with potential applications in various industries.
Used in Pharmaceutical Chemistry:
In the pharmaceutical industry, 2-Phenylthiopyridine is used as a potential ligand in coordination chemistry, which can lead to the development of new drugs with improved properties. Its unique structure and reactivity make it a promising candidate for the design and synthesis of novel pharmaceutical compounds.
Used in Anticancer Research:
2-Phenylthiopyridine has been investigated for its potential biological activity, particularly as an anticancer agent. Its unique structure and reactivity may contribute to the development of new therapeutic agents for the treatment of various types of cancer.
Used in Coordination Chemistry:
In coordination chemistry, 2-Phenylthiopyridine is used as a potential ligand to form coordination complexes with metal ions. These complexes can exhibit unique properties and reactivity, making them valuable for various applications, such as catalysis, sensing, and materials science.

InChI:InChI=1/C11H9NS/c1-2-6-10(7-3-1)13-11-8-4-5-9-12-11/h1-9H

Upstream product

• 109-09-1 2-chloropyridine 
• 108-98-5 thiophenol 
• 109-04-6 2-bromo-pyridine 
• 2637-34-5 pyridine-2-thione 
• 938-81-8 N-nitrosoacetanilide 
• 981-18-0 triphenyl(phenylazo)methane 
• 13133-62-5 thiophenolate 
• 930-69-8 sodium thiophenolate 
• 17314-33-9 tributyltin phenyl sulfide 
• 5029-67-4 2-iodopyridine 
• 108-86-1 bromobenzene 
• 13327-62-3 2-mercaptopyridine sodium salt 
• 4262-06-0 di-2-pyridyl sulfide 
• 882-33-7 diphenyldisulfane 

Downstream Products

• 89818-46-2 phenyl 2-pyridyl sulphoxide 
• 1008-89-5 2-phenylpyridine 
• 366-18-7 [2,2]bipyridinyl 
• 945-51-7 1,1'-sulfinylbisbenzene 
• 882-33-7 diphenyldisulfane 
• 220693-31-2 [AuCl₃(NC₅H₄(SC₆H₅))] 
• 220693-29-8 C₅H₅N(SC₆H₅)⁽¹⁺⁾*AuCl₄^(1-) = [C₅H₅N(SC₆H₅)][AuCl₄] 
• 1279130-32-3 2-(2-pyridinylsulfinyl)phenyl acetate 
• 220693-37-8 [AuCl₂(P(C₆H₅)3)(NC₅H₄SC₆H₄)] 
• 1329491-64-6 2-[(3'-methylbiphenyl-2-yl)sulfinyl]pyridine 
• 1345470-50-9 2-[(3'-chlorobiphenyl-2-yl)sulfinyl]pyridine 
• 1370652-62-2 2-(3'-fluorobiphenyl-2-ylsulfinyl)pyridine 
• 24244-60-8 2-(phenylsulfonyl)pyridine 
• 1289560-25-3 2-{2-[(E)-styryl]phenylsulfinyl}pyridine 

Relevant academic research and scientific papers

Dimsyl Anion Enables Visible-Light-Promoted Charge Transfer in Cross-Coupling Reactions of Aryl Halides

A methodology is reported for visible-light-promoted synthesis of unsymmetrical chalcogenides enabled by dimsyl anion in the absence of transition-metals or photoredox catalysts. The cross-coupling reaction between aryl halides and diaryl dichalcogenides proceeds with electron-rich, electron-poor, and heteroaromatic moieties. Mechanistic investigations using UV-Vis spectroscopy, time-dependent density functional theory (TD-DFT) calculations, and control reactions suggest that dimsyl anion forms an electron-donor-acceptor (EDA) complex capable of absorbing blue light, leading to a charge transfer responsible for generation of aryl radicals from aryl halides. This previously unreported mechanistic pathway may be applied to other light-induced transformations performed in DMSO in the presence of bases and aryl halides.

Ni(II) Precatalysts Enable Thioetherification of (Hetero)Aryl Halides and Tosylates and Tandem C?S/C?N Couplings

Ni-catalyzed C?S cross-coupling reactions have received less attention compared with other C-heteroatom couplings. Most reported examples comprise the thioetherification of most reactive aryl iodides with aromatic thiols. The use of C?O electrophiles in this context is almost uncharted. Here, we describe that preformed Ni(II) precatalysts of the type NiCl(allyl)(PMe2Ar’) (Ar’=terphenyl group) efficiently couple a wide range of (hetero)aryl halides, including challenging aryl chlorides, with a variety of aromatic and aliphatic thiols. Aryl and alkenyl tosylates are also well tolerated, demonstrating, for the first time, to be competent electrophilic partners in Ni-catalyzed C?S bond formation. The chemoselective functionalization of the C?I bond in the presence of a C?Cl bond allows for designing site-selective tandem C?S/C?N couplings. The formation of the two C-heteroatom bonds takes place in a single operation and represents a rare example of dual electrophile/nucleophile chemoselective process.

2-Pyridyl Sulfoxide Directed Pd(II)-Catalyzed C-H Olefination of Arenes with Molecular Oxygen as the Sole Oxidant

Pd(II)-catalyzed C-H olefination of aryl 2-pyridyl sulfoxides with unactivated and activated olefins has been demonstrated. We employed environmentally benign and inexpensive molecular oxygen as the sole oxidant. The versatile nature of the 2-pyridyl sulf

Photo-induced thiolate catalytic activation of inert Caryl-hetero bonds for radical borylation

Substantial effort is currently being devoted to obtaining photoredox catalysts with high redox power. Yet, it remains challenging to apply the currently established methods to the activation of bonds with high bond dissociation energy and to substrates with high reduction potentials. Herein, we introduce a novel photocatalytic strategy for the activation of inert substituted arenes for aryl borylation by using thiolate as a catalyst. This catalytic system exhibits strong reducing ability and engages non-activated Caryl–F, Caryl–X, Caryl–O, Caryl–N, and Caryl–S bonds in productive radical borylation reactions, thus expanding the available aryl radical precursor scope. Despite its high reducing power, the method has a broad substrate scope and good functional-group tolerance. Spectroscopic investigations and control experiments suggest the formation of a charge-transfer complex as the key step to activate the substrates.

Copper pyrithione (CuPT)-catalyzed/mediated amination and thioarylation of (hetero)aryl halides: A competition

A facile method for the synthesis of N-arylheterocycles and di(hetero)aryl sulfides under mild condition is described. In these transformations, copper pyrithione (CuPT) was used as the copper catalyst for C─N coupling, while served as catalyst and coupled partner for C─S coupling with high yields and broad substrate tolerance. The S-arylation process was also utilized for the construction of valuable bioactive 2-sulfonylpyridine 1-oxide derivatives.

Microwave-Assisted Copper Slag-Catalyzed Green S-Arylation of Arenethiols with Arylboronic Acids

Abstract: Diaryl sulfides have been synthesized in moderate to excellent yield by S-arylation of arenethiols with arylboronic acids using copper slag as a catalyst. Copper slag is a by-product obtained from smelting and refining of copper. Conventional heating method has been compared with the microwave-assisted technique. The proposed microwave-assisted synthesis provides excellent yields of diaryl sulfides in a short time (10 min) and is ligand-free, green, and cost-effective.

Synthesis of thioethers, arenes and arylated benzoxazoles by transformation of the C(aryl)-C bond of aryl alcohols

Transformation of aryl alcohols into high-value functionalized aromatic compounds by selective cleavage and functionalization of the C(aryl)-C(OH) bond is of crucial importance, but very challenging by far. Herein, for the first time, we report a novel and versatile strategy for activation and functionalization of C(aryl)-C(OH) bonds by the cooperation of oxygenation and decarboxylative functionalization. A diverse range of aryl alcohol substrates were employed as arylation reagents via the cleavage of C(aryl)-C(OH) bonds and effectively converted into corresponding thioether, arene, and arylated benzoxazole products in excellent yields, in a Cu based catalytic system using O2 as the oxidant. This study offers a new way for aryl alcohol conversion and potentially offers a new opportunity to produce high-value functionalized aromatics from renewable feedstocks such as lignin which features abundant C(aryl)-C(OH) bonds in its linkages.

DABCO-promoted Diaryl Thioether Formation by Metal-catalyzed Coupling of Sodium Sulfinates and Aryl Iodides

A scalable catalytic synthesis method using commodity chemicals for constructing diaryl thioethers directly from sodium arylsulfinates and iodoarenes is reported in this study. In the presence of CuO or other copper salts such as Cu(OAc)2 as well as palladium catalysts, DABCO demonstrated to be essential to promote this transformation. Various iodoarenes and aryl sulfinates were examined and demonstrated the viability of this method. The mechanistic study showed that radical reactions occurred, while DABCO N-oxide radical can be observed by mass spectrometry. A plausible catalytic mechanism involving DABCO is also discussed, suggesting synergistic reduction of sulfinate by Cu(II) and DABCO is the key step of this coupling reaction. (Figure presented.).

General Method for the Asymmetric Synthesis of N-H Sulfoximines via C-S Bond Formation

A versatile method for the synthesis of enantioenriched N-H sulfoximines is reported. The approach stems from the organomagnesium-mediated ring opening of novel cyclic sulfonimidate templates. The reactions proceed in high yield and with excellent stereofidelity with alkyl, aryl, and heteroaryl Grignard reagents. The chiral auxiliary is readily removed from the resultant sulfoximines via an unusual oxidative debenzylation protocol that utilizes molecular oxygen as the terminal oxidant. This provides a general strategy for the synthesis of highly enantioenriched N-H sulfoximines.

A semiconducting supramolecular Co(ii)-metallohydrogel: an efficient catalyst for single-pot aryl-S bond formation at room temperature

A novel mechanically stable supramolecular Co(ii)-metallohydrogel has been synthesized. Cobalt(ii) nitrate hexahydrate and monoethanolamine, as a low molecular weight organic gelator, are used to get the gel. The mechanical stability of the supramolecular hydrogel was analyzed. The morphology of the supramolecular metallohydrogel was scrutinized. The semiconducting features of the metallohydrogel were studied. The conducting properties of the Co(ii)-metallohydrogel establish a Schottky barrier diode type nature. The catalytic nature of the Co(ii)-metallohydrogel based room temperature single pot aryl-S coupling reaction was explored. Most interestingly, the Co(ii)-metallohydrogel based catalytic aryl-S coupling reaction does not require any column-chromatographic purification protocol to get pure aryl-thioethers. Thus, through this work a semiconducting Schottky barrier diode application and catalytic role in the room temperature single pot aryl-S coupling reaction of a supramolecular Co(ii)-metallohydrogel have been explored.