10436-83-6

Basic information

• Product Name: S-(4-methylphenyl) ethanethioate
• Synonyms: S-(4-methylphenyl) ethanethioate;1-(Acetylthio)-4-methylbenzene;4-Methyl-1-(acetylthio)benzene;Ethanethioic acid S-(4-methylphenyl) ester;Thioacetic acid S-(4-methylphenyl) ester;Thioacetic acid S-(p-methylphenyl) ester;Einecs 233-921-3;S-(P-TOLYL) THIOACETATE
• CAS NO: 10436-83-6
• Molecular Formula: C₉H₁₀OS
• Molecular Weight: 166.2401
• EINECS: 233-921-3
• Mol File: 10436-83-6.mol
• Article Data: 65

Chemical Properties

• Boiling Point: 256°C at 760 mmHg
• Flash Point: 105.1°C
• Appearance: /
• Density: 1.1g/cm³
• Vapor Pressure: 0.0158mmHg at 25°C
• Refractive Index: 1.563
• CAS DataBase Reference: S-(4-methylphenyl) ethanethioate(CAS DataBase Reference)
• NIST Chemistry Reference: S-(4-methylphenyl) ethanethioate(10436-83-6)
• EPA Substance Registry System: S-(4-methylphenyl) ethanethioate(10436-83-6)

Safety Data

• Hazardous Substances Data: 10436-83-6(Hazardous Substances Data)

Usage

Synthesis Reference(s)

Journal of the American Chemical Society, 117, p. 6489, 1995 DOI: 10.1021/ja00129a011

InChI:InChI=1/C9H10OS/c1-7-3-5-9(6-4-7)11-8(2)10/h3-6H,1-2H3

Upstream product

• 98215-06-6 1-lithio-1,1-bis(p-tolylthio)-methane 
• 100-99-2 triisobutylaluminum 
• 75-36-5 acetyl chloride 
• 108-22-5 Isopropenyl acetate 
• 106-45-6 para-thiocresol 
• 624-31-7 4-tolyl iodide 
• 10387-40-3 potassium thioacetate 
• 115981-42-5 methyl(4-methyl-benzenethiolato){1,2-bis(diphenylphosphino)ethane}nickel 
• 106-38-7 para-bromotoluene 
• 1971-49-9 N-acetylphthalimide 
• 7439-10-3 tert-butyl 4-methylphenyl sulfide 
• 34832-35-4 sodium thioacetate 
• 103-19-5 di(p-tolyl) disulfide 
• 82479-13-8 3-oxo-3-(4-methylphenylthio)propanoic acid 

Downstream Products

• 106-45-6 para-thiocresol 
• 122-00-9 para-methylacetophenone 
• 49591-70-0 N-t-butyl-4-methylbenzenesulfinimidoyl chloride 
• 16601-19-7 1-(benzyl)-2-(4-methylphenyl)disulfide 
• 83180-92-1 1-(4-methylphenyldisulfanyl)-4-methoxybenzene 
• 1055876-47-5 2,5-difluoro-1,3,4-tris(p-tolylthio)benzene 
• 1055876-56-6 2,5-difluoro-1,4-bis(p-tolylthio)benzene 
• 1055876-61-3 3,5-difluoro-1-(p-tolylthio)benzene 
• 124254-98-4 C₉H₉BrOS 

Relevant articles and documents

Leaving Group Effects in Thiolester Hydrolysis. Part 2. On the Possibility of an Elimination-Addition (Keten) Mediated Pathway in S-Acetylcoenzyme A Basic Hydrolysis and Acetyl Transfer

Alkaline hydrolysis rates (kHO(1-)) at 25 deg C in aqueous solution for a series of S-alkyl and S-aryl thiolacetates, including S-acetylcoenzyme A, were correlated (as their logarithms) with the pKa of the conjugate acid of the thiolate leaving group to give a slope (βl.g.) of -0.33.In comparison with the corresponding oxygen esters, thiolesters are, for the basicity of a given leaving species, one to two orders of magnitude less reactive towards hydroxide ion and show little dispersion into aryl and alkyl leaving groups, ascribed to the lower steric sensitivity of thiolacetate esters compared with the oxygen analogues.The small value of βl.g. and the lower reactivity of S- than O-esters are offered as evidence of a bimolecular associative (BAc2) mechanism for basic hydrolysis.The E2 route is excluded by the lack of deuterium incorporation into the (acetate) product of hydrolysis.In spite of the accepted acidity of thiolacetates, a kinetically insignificant amount of ester conjugate base is formed in aqueous solution even at high, non-physiological pH and thus S-acetylcoenzyme A does not hydrolyse by an E1cB pathway.

Ruthenium(III) chloride catalyzed acylation of alcohols, phenols, and thiols in room temperature Ionic liquids

Ruthenium(III) chloride-catalyzed acylation of a variety of alcohols, phenols, and thiols was achieved in high yields under mild conditions (room temperature) in the ionic liquid 1-butyl-3-methylimidazolium hexafluorophosphate ([bmim][PF6]). The ionic liquid and ruthenium catalyst can be recycled at least 10 times. Our system not only solves the basic problem of ruthenium catalyst reuse, but also avoids the use of volatile acetonitrile as solvent.

NiNP@rGO Nanocomposites as Heterogeneous Catalysts for Thiocarboxylation Cross-Coupling Reactions

A new type of ligand-free Ni-nanoparticles supported on rGO (size distribution average d = 9 ± 3 nm) was prepared and fully characterized via morphological (Fe-SEM), structural (P-XRD, HR-TEM), and spectroscopic (ICP-EOS, XPS) analysis tools. The metal composite was effectively employed in the unprecedented heterogeneously Ni-assisted cross-coupling reaction of aryl/vinyl iodides and thiocarboxylates. A range of sulfur-containing aryl as well as vinyl derivatives (15 examples) was achieved in high yields (up to 82%), under mild reaction conditions, and with wide functional group tolerance.

Magnetically recyclable silica-coated ferrite magnetite-K10montmorillonite nanocatalyst and its applications in O, N, and S-acylation reaction under solvent-free conditions

Novel silica-coated ferrite nanoparticles supported with montmorillonite (K10) have been prepared successfully by using a simple impregnation method. Further, these nanoparticles were characterized by using different analytical methods like FT-IR, PXRD, EDS, and FE-SEM techniques. In addition, these nanoparticles have been explored for their catalytic activity for the O, N, and S-acylation reactions under solvent-free conditions which gave moderate to excellent yields in a much shorter reaction time. Moreover, these nanoparticles could easily be separated out from the reaction medium after the reaction completion by using an external magnetic field and have been re-used for 10 cycles without any significant loss of the catalytic activity.

Unsymmetrical Disulfides Synthesis via Cs2CO3-Catalyzed Three-Component Reaction in Water

An unsymmetrical disulfides synthesis by Cs2CO3-catalyzed three-component coupling reaction of thioacetate, sodium thiosulfate, and benzyl halide in water is described. The safe, stable, and non-toxic Na2S2O3 was invoked as the sulfur-source, successfully avoiding the odor generation in the process of S?S bond formation. A wide range of substrate suitability and appropriate functional group tolerance were observed for the transformation. Notably, the approach reported here was compatible with various biomolecules including glucose, coumarin, and quinolinone. (Figure presented.).