21722-85-0

Basic information

• Product Name: Inezin
• Synonyms: ESBP;Phenylphosphonothioic acid O-ethyl S-(phenylmethyl) ester;Phenylthiophosphonic acid O-ethyl S-benzyl ester;[ethoxy(phenylMethylsulfanyl)phosphoryl]benzene
• CAS NO: 21722-85-0
• Molecular Formula: C₁₅H₁₇O₂PS
• Molecular Weight: 292.33
• Mol File: 21722-85-0.mol

Chemical Properties

• Boiling Point: 406.1°C at 760 mmHg
• Flash Point: 199.4°C
• Appearance: /
• Density: 1.19g/cm³
• Vapor Pressure: 1.96E-06mmHg at 25°C
• Refractive Index: 1.58
• CAS DataBase Reference: Inezin(CAS DataBase Reference)
• NIST Chemistry Reference: Inezin(21722-85-0)
• EPA Substance Registry System: Inezin(21722-85-0)

Safety Data

• Hazardous Substances Data: 21722-85-0(Hazardous Substances Data)

Usage

InChI:InChI=1/C15H17O2PS/c1-2-17-18(16,15-11-7-4-8-12-15)19-13-14-9-5-3-6-10-14/h3-12H,2,13H2,1H3

Upstream product

• 3012-37-1 benzyl thiocyanate 
• 172487-18-2 ethyl Phenylphosphinate 
• 36331-57-4 benzylsulfonylhydrazide 
• 1939-99-7 benzenesulfonyl chloride 
• 100-53-8 phenylmethanethiol 
• 100-39-0 benzyl bromide 
• 76003-54-8 Dicyclohexyl-amine; compound with phenyl-phosphonothioic acid O-ethyl ester 

Relevant articles and documents

Tf2O/DMSO-Promoted P-O and P-S Bond Formation: A Scalable Synthesis of Multifarious Organophosphinates and Thiophosphates

A Tf2O/DMSO-based system for the dehydrogenative coupling of a wide range of alcohols, phenols, thiols, and thiophenols with diverse phosphorus reagents has been developed. This metal- and strong-oxidant-free strategy provides a facile approach to a great variety of organophosphinates and thiophosphates. The simple reaction system, good functional-group tolerance, and broad substrate scope enable the application of this method to the modification of natural products and the direct synthesis of bioactive molecules and flame retardants.

An Alternative Metal-Free Aerobic Oxidative Cross-Dehydrogenative Coupling of Sulfonyl Hydrazides with Secondary Phosphine Oxides

An alternative metal-free, efficient and practical approach for the preparation of phosphinothioates is established via the aerobic oxidative cross-dehydrogenative coupling (CDC) of sulfonyl hydrazides with secondary phosphine oxides catalyzed by tetrabutylammonium iodide (TBAI) in the presence of atmospheric oxygen. The strategy provides an array of diverse phosphinothioates in good to excellent yields. Furthermore, two representative bioactive molecules are synthesized on up to gram scale by utilizing this method.

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.

TBPB-promoted metal-free synthesis of thiophosphinate/phosphonothioate by direct P-S bond coupling

An efficient method for the direct coupling of thiol/thiophenol with H-phosphine oxides or H-phosphinate esters is reported. Without using any metallic catalyst, the direct sulfur-phosphorus bond coupling reaction was promoted using tert-butyl peroxybenzo

Easy access to phosphonothioates.

A new and particularly mild method for the formation of phosphorus-sulfur bonds has been achieved through base-catalyzed addition of thiocyanate to the corresponding H-phosphine oxide, phosphinate, or phosphonate. This reaction procedure offers many advantages: the use as starting material of a stable and not oxygen-sensitive phosphorus(v) species, particularly mild and nonaqueous reaction conditions and workup (a pivotal point for these sensitive phosphonothioates), and, through optimized access to thiocyanates, a wider scope of substrates. This method has been applied to achieve the synthesis of substrate analogues for the study of antibody-catalyzed hydrolysis of acetylcholinesterase inhibitor PhX (11).

EVIDENCE FOR SELECTIVE S-ALKYLATION OF AN AMBIDENT ANION OF DICYCLOHEXYLAMMONIUM THIOPHOSPHONATE BY ALKYL HALIDES

Reaction of DCHA salt of O-alkyl phenyl phosphonothioic acids 1a-c with alkyl halides 2a-d gave exclusively S-derivatives; 3e-h (85-93percent) and 3b-d (40-43percent).The cause for poor yields of the methyl analogues is its ability to participate in the methylation of salt 1a and give rise by-product O,S-dimethyl phenyl phosphonothiolate (3a).Awareness of the unusual pathway for the generation of the by-product has opened a new possibility to adopt this strategy for synthesis of enantiomerically pure thiolates. Key words: Chiral phosphonothiolates; dicyclohexylammonium thiophosphonate anion; resolution; stereospecific synthesis; cross methylation; alkyl halides.