31218-75-4

Basic information

• Product Name: 4-ETHYLTHIOANISOLE
• Synonyms: 4-ETHYLTHIOANISOLE
• CAS NO: 31218-75-4
• Molecular Formula: C₉H₁₂S
• Molecular Weight: 152.26
• Mol File: 31218-75-4.mol

Chemical Properties

• Appearance: /
• CAS DataBase Reference: 4-ETHYLTHIOANISOLE(CAS DataBase Reference)
• NIST Chemistry Reference: 4-ETHYLTHIOANISOLE(31218-75-4)
• EPA Substance Registry System: 4-ETHYLTHIOANISOLE(31218-75-4)

Safety Data

• Hazardous Substances Data: 31218-75-4(Hazardous Substances Data)

Upstream product

• 1778-09-2 4-(Methylthio)acetophenone 
• 623-13-2 4-methylphenyl methylsulfide 
• 74-88-4 methyl iodide 
• 53120-15-3 1-Ethyl-4-methanesulfinyl-benzene 
• 104-95-0 (4-bromophenyl)thioanisole 
• 75-03-6 ethyl iodide 
• 18760-11-7 4-methythiostyrene 

Downstream Products

• 458-99-1 (4-ethylphenyl)(trifluoromethyl)sulfane 
• 74-87-3 methylene chloride 
• 4946-13-8 4-ethylbenzenethiol 
• 3753-23-9 Tris-(p-ethyl-phenylthio)-phosphin 
• 123159-39-7 3,6-Diethyl-9,10-dithia-4b,9a-diphospha-indeno[1,2-a]indene 
• 53120-15-3 1-Ethyl-4-methanesulfinyl-benzene 
• 69738-09-6 5-ethyl-2-(methylthio)benzophenone 
• 69738-06-3 5-ethyl-4'-methyl-2-(methylthio)benzophenone 
• 69738-08-5 2-(methylthio)-5-ethyl-4'-chlorobenzophenone 
• 22905-10-8 1-ethyl-4-(ethylthio)benzene 
• 158321-97-2 1-ethyl-4-(ethylthio)-3-methylbenzene 
• 58348-10-0 2-[(4-ethylphenyl)thio]acetic acid 
• 620-14-4 1-Methyl-3-ethylbenzene 
• 69738-15-4 2-(methylsulfinyl)-5-ethyl-4'-methylbenzophenone 

Relevant articles and documents

Metal-Organic Framework-Confined Single-Site Base-Metal Catalyst for Chemoselective Hydrodeoxygenation of Carbonyls and Alcohols

Chemoselective deoxygenation of carbonyls and alcohols using hydrogen by heterogeneous base-metal catalysts is crucial for the sustainable production of fine chemicals and biofuels. We report an aluminum metal-organic framework (DUT-5) node support cobalt(II) hydride, which is a highly chemoselective and recyclable heterogeneous catalyst for deoxygenation of a range of aromatic and aliphatic ketones, aldehydes, and primary and secondary alcohols, including biomass-derived substrates under 1 bar H2. The single-site cobalt catalyst (DUT-5-CoH) was easily prepared by postsynthetic metalation of the secondary building units (SBUs) of DUT-5 with CoCl2 followed by the reaction of NaEt3BH. X-ray photoelectron spectroscopy and X-ray absorption near-edge spectroscopy (XANES) indicated the presence of CoII and AlIII centers in DUT-5-CoH and DUT-5-Co after catalysis. The coordination environment of the cobalt center of DUT-5-Co before and after catalysis was established by extended X-ray fine structure spectroscopy (EXAFS) and density functional theory. The kinetic and computational data suggest reversible carbonyl coordination to cobalt preceding the turnover-limiting step, which involves 1,2-insertion of the coordinated carbonyl into the cobalt-hydride bond. The unique coordination environment of the cobalt ion ligated by oxo-nodes within the porous framework and the rate independency on the pressure of H2 allow the deoxygenation reactions chemoselectively under ambient hydrogen pressure.

Transfer Hydrogenation of Alkenes Using Ethanol Catalyzed by a NCP Pincer Iridium Complex: Scope and Mechanism

The first general catalytic approach to effecting transfer hydrogenation (TH) of unactivated alkenes using ethanol as the hydrogen source is described. A new NCP-type pincer iridium complex (BQ-NCOP)IrHCl containing a rigid benzoquinoline backbone has been developed for efficient, mild TH of unactivated C-C multiple bonds with ethanol, forming ethyl acetate as the sole byproduct. A wide variety of alkenes, including multisubstituted alkyl alkenes, aryl alkenes, and heteroatom-substituted alkenes, as well as O- or N-containing heteroarenes and internal alkynes, are suitable substrates. Importantly, the (BQ-NCOP)Ir/EtOH system exhibits high chemoselectivity for alkene hydrogenation in the presence of reactive functional groups, such as ketones and carboxylic acids. Furthermore, the reaction with C2D5OD provides a convenient route to deuterium-labeled compounds. Detailed kinetic and mechanistic studies have revealed that monosubstituted alkenes (e.g., 1-octene, styrene) and multisubstituted alkenes (e.g., cyclooctene (COE)) exhibit fundamental mechanistic difference. The OH group of ethanol displays a normal kinetic isotope effect (KIE) in the reaction of styrene, but a substantial inverse KIE in the case of COE. The catalysis of styrene or 1-octene with relatively strong binding affinity to the Ir(I) center has (BQ-NCOP)IrI(alkene) adduct as an off-cycle catalyst resting state, and the rate law shows a positive order in EtOH, inverse first-order in styrene, and first-order in the catalyst. In contrast, the catalysis of COE has an off-cycle catalyst resting state of (BQ-NCOP)IrIII(H)[O(Et)···HO(Et)···HOEt] that features a six-membered iridacycle consisting of two hydrogen-bonds between one EtO ligand and two EtOH molecules, one of which is coordinated to the Ir(III) center. The rate law shows a negative order in EtOH, zeroth-order in COE, and first-order in the catalyst. The observed inverse KIE corresponds to an inverse equilibrium isotope effect for the pre-equilibrium formation of (BQ-NCOP)IrIII(H)(OEt) from the catalyst resting state via ethanol dissociation. Regardless of the substrate, ethanol dehydrogenation is the slow segment of the catalytic cycle, while alkene hydrogenation occurs readily following the rate-determining step, that is, β-hydride elimination of (BQ-NCOP)Ir(H)(OEt) to form (BQ-NCOP)Ir(H)2 and acetaldehyde. The latter is effectively converted to innocent ethyl acetate under the catalytic conditions, thus avoiding the catalyst poisoning via iridium-mediated decarbonylation of acetaldehyde.

Metallation reactions. Part 35: A change of the regiochemistry in the metallation of (alkylthio)arenes

The metallation reaction of bromo(alkylthio)benzenes is described. The results show the complementarity of these reactions with the metal-hydrogen exchange reaction. In fact, monometallation of bromo(methylthio)benzenes afforded products substituted in para or meta or ortho to the thioethereal function while bimetallation led to αS,para, αS,meta and αS,ortho disubstituted products. Analogously, the monometallation of 4-bromo-(isopropylthio)benzene afforded para-monosubstituted and ortho,para-disubstituted products.

Deoxygenation of sulphoxides on irradiated TiO2 surfaces

Irradiation of solutions of sulphoxides in organic solvents in the presence of suspended TiO2 results in the deoxygenation giving sulphides in fairly good yields. The mechanism involves the transfer of an electron from the conduction band of the semiconductor to the sulphoxide.

Metallation reactions. XXI. Metallation of alkyl (alkylthio) benzenes by superbases versus organolithium compounds

The metallation regiochemistry of alkyl(alkylthio)benzenes with butyllithium or with the superbasic mixture of butyllithium with potassium tert-butoxide is described. The reaction pattern depends on the substrate and the reagent. Butyllithium monometallates the thiomethylic carbon of methyl (methylthio) benzenes and bimetallates the thiomethylic and the annular carbon ortho to the thioethereal group. With superbases the metallation occurs at the thiomethylic and methylic carbon. Metallation with butyllithium of the higher homologs substitutes exclusively the hydrogen ortho to the thioalkylic group, while the superbases attack also the carbon atom alpha to the thioalkyl substituent.