15224-36-9

Upstream product

• 98-58-8 4-bromobenzenesulfonyl chloride 
• 122-52-1 triethyl phosphite 
• 5335-84-2 bis(4-bromophenyl)disulfide 
• 762-04-9 phosphonic acid diethyl ester 
• 106-53-6 para-bromobenzenethiol 
• 5467-74-3 4-Bromophenylboronic acid 
• 1762-76-1 4-bromobenzenesulfenyl chloride 
• 13716-45-5 diethyl trimethylsilyl phosphite 
• 673-40-5 4-bromobenzenediazonium tetrafluoroborate 
• 1203709-75-4 4-bromo-2,4,6-trimethyldiphenyliodonium trifluoromethanesulfonate 
• 2297-64-5 p-bromophenylsulfonyl hydrazide 

Downstream Products

• 1062609-73-7 4-bromophenyltetetrafluoro-λ⁶-sulfanyl chloride 
• 774-93-6 1-bromo-4-pentafluorosulfanylbenzene 

Relevant academic research and scientific papers

A green and efficient route for P ? S ? C bond construction using copper ferrite nanoparticles as catalyst: a TD-DFT study

Magnetic nanoparticles of CuFe2O4 were applied as catalyst system for one-pot thiophosphate synthesis via the reaction of aryl sulfonyl chlorides with H-phosphonates under conventional heating conditions. This is an extremely efficient and green method for thiophosphate synthesis under base- and solvent-free conditions. Various thiophosphates were obtained in good to excellent yields under the optimized reaction conditions in a short time. The catalyst can be easily recycled from the reaction by an external magnetic field and reused for the next run. In this study, TD-DFT B3LYP/6-31 + G(d) calculations are in good accord with the experimental results. A comparison between experimental and theoretical UV-vis absorption spectra of the thiophosphate 3k has been carried out; and a small hypsochromic shift (only ～ 2 nm) was displayed at maximum absorption. The aim of this work is to investigate the best method and basis set for thiophosphate compounds; therefore, predictions for these compounds can be performed in theoretical studies.

Electrochemically driven synthesis of phosphorothioates from trialkyl phosphites and aryl thiols

A facile and elegant protocol for synthesis of phosphorothioates from trialkyl phosphites and aryl thiols via indirect electrochemical oxidation mediated by KI has been successfully developed. KI as a redox mediator, enabled the reaction of trialkyl phosp

Validation of Arylphosphorothiolates as Convergent Substrates for Ar-SF 4Cl and Ar-SF 5Synthesis

In this manuscript we describe the oxidative fluorination of aryl phosphorothiolates to access Ar-SF4Cl compounds. These compounds serve as precursors for the highly coveted Ar-SF5 compounds. The use of phosphorothiolates as starting materials permits access to Ar-SF4Cl from a wide variety of available starting materials, namely boronic acids, diazonium salts, aryl iodides, thiophenols, or simple arenes. The protocol has been demonstrated for 10 examples and showed good tolerance to various functional groups. Finally, we demonstrated that AgBF4 can be used as a fluorinating agent, affording good yields of an Ar-SF5.

Synthetic method of thiophosphate compound

The invention discloses a synthetic method of a phosphorothioate compound. The preparation method comprises the following steps: with thiol as a reaction substrate and trichloroisocyanuric acid (TCCA)as an accelerant, reacting the reaction substrate and the accelerant in an organic solvent at normal temperature and normal pressure for 10-20 minutes, then adding phosphite triester, continuing reacting for 10-20 minutes, and after the reaction is finished, carrying out separation treatment to obtain the phosphorothioate compound. According to the synthesis method disclosed by the invention, thereaction is carried out at normal temperature and normal pressure without special requirements; reaction time is short; and reaction substrate universality is good.

Trichloroisocyanuric acid-promoted thiolation of phosphites by thiols

A simple and convenient method for the synthesis of thiophosphates by coupling of phosphites with thiols under mild conditions has been developed. The reactions were promoted by trichloroisocyanuric acid (TCCA) and were carried out at room temperature in

Lewis Acid Promoted Aerobic Oxidative Coupling of Thiols with Phosphonates by Simple Nickel(II) Catalyst: Substrate Scope and Mechanistic Studies

Exploring new catalysts for efficient organic synthesis is among the most attractive topics in chemistry. Here, using Ni(OAc)2/LA as catalyst (LA: Lewis acid), a novel catalyst strategy was developed for oxidative coupling of thiols and phosphonates to phosphorothioates with oxygen oxidant. The present study discloses that when Ni(OAc)2 alone was employed as the catalyst, the reaction proceeded very sluggishly with low yield, whereas adding non-redox-active metal ions such as Y3+ to Ni(OAc)2 dramatically promoted its catalytic efficiency. The promotional effect is highly Lewis acidity dependent on the added Lewis acid, and generally, a stronger Lewis acid provided a better promotional effect. The stopped-flow kinetics confirmed that adding Y(OTf)3 can obviously accelerate the activation of thiols by Ni(II) and next accelerate its reaction with phosphonate to generate the phosphorothioate product. ESI-MS characterizations of the catalyst disclosed the formation of the heterobimetallic Ni(II)/Y(III) species in the catalyst solution. Additionally, this Ni(II)/LA catalyst can be applied in the synthesis of a series of phosphorothioate compounds including several commercial bioactive compounds. This catalyst strategy has clearly supported that Lewis acid can significantly improve the catalytic efficiency of these traditional metal ions in organic synthesis, thus opening up new opportunities in their catalyst design.

Synthetic method for phosphorothiolate compounds

The invention discloses a synthetic method for phosphorothiolate compounds, and the reaction steps of the synthetic method are as follows: dissolving diaryl disulfide in the solution, taking oxygen inthe air as an oxidizing agent, stirring at room tempera

Reactions of Disulfides with Silyl Phosphites to Generate Thiophosphates Under Neat Conditions

An efficient procedure for the synthesis of thiophosphates is described. Without using any metallic catalyst or base, the direct sulfur–phosphorus coupling reaction of disulfides and dialkyl trimethylsilyl phosphite (DTSP) was carried out under solvent-fr

Base-controlled Fe(Pc)-catalyzed aerobic oxidation of thiols for the synthesis of S-S and S-P(O) bonds

Fe(Pc)-Catalyzed aerobic oxidation of thiols for the synthesis of disulfides has been developed under mild reaction conditions. In addition, an aerobic oxidative cross-dehydrogenative coupling (CDC) reaction of thiols with P(O)-H compounds (H-phosphonates and H-phosphine oxide) for the formation of S-P(O) bonds has been demonstrated under the Fe(Pc) catalysis system with a base additive. Control experiments revealed that the use of a base (DIPA) in this system controls the synthetic pathways in which thiophosphates are formed.

K2CO3-promoted aerobic oxidative cross-coupling of trialkyl phosphites with thiophenols

Convenient, practical and economical phosphorylation of thiols has been achieved via halogen- and metal-free K2CO3-promoted aerobic oxidative cross-coupling of trialkyl phosphites, dimethyl phenylphosphonite, or methyl diphenylphosphinite with thiophenols using air as the oxidant at room temperature. This transformation provides a straightforward route to the construction of phosphorus-sulfur bonds with wide functional group compatibility, which affords phosphorothioates in up to 94% yield.