10568-38-4

Basic information

• Product Name: 3-Ethylphenyl(methyl) ether
• Synonyms: 1-Ethyl-3-methoxybenzene;3-Ethylanisole;3-Ethylphenyl(methyl) ether;m-Ethylanisole
• CAS NO: 10568-38-4
• Molecular Formula: C₉H₁₂O
• Molecular Weight: 136.191
• Mol File: 10568-38-4.mol
• Article Data: 21

Chemical Properties

• Boiling Point: 197°C (estimate)
• Flash Point: 68.3°C
• Appearance: /
• Density: 0.9575
• Vapor Pressure: 0.761mmHg at 25°C
• Refractive Index: 1.5102
• CAS DataBase Reference: 3-Ethylphenyl(methyl) ether(CAS DataBase Reference)
• NIST Chemistry Reference: 3-Ethylphenyl(methyl) ether(10568-38-4)
• EPA Substance Registry System: 3-Ethylphenyl(methyl) ether(10568-38-4)

Safety Data

• Hazardous Substances Data: 10568-38-4(Hazardous Substances Data)

Usage

Description

3-Ethylphenyl(methyl) ether, also known as 1-(3-ethylphenyl)ethan-1-one or ethyl-3-methoxyphenyl ketone, is a chemical compound with the molecular formula C9H12O. It is a colorless liquid characterized by a sweet, floral odor and is recognized for its high purity and stability.

Uses

Used in the Food Industry:
3-Ethylphenyl(methyl) ether is used as a flavoring ingredient for its distinctive sweet, floral aroma, enhancing the taste and appeal of various food products.
Used in the Cosmetic Industry:
In the cosmetic industry, 3-Ethylphenyl(methyl) ether serves as a fragrance, adding a pleasant scent to products while maintaining a high level of safety when used appropriately.
Used in Pharmaceutical Synthesis:
3-Ethylphenyl(methyl) ether is utilized in the synthesis of pharmaceuticals, contributing to the development of new medications and organic compounds due to its chemical properties.
Used in Organic Compound Synthesis:
Beyond pharmaceuticals, 3-Ethylphenyl(methyl) ether is also employed in the synthesis of other organic compounds, showcasing its versatility in chemical reactions and applications.

InChI:InChI=1/C9H12O/c1-3-8-5-4-6-9(7-8)10-2/h4-7H,3H2,1-2H3

Upstream product

• 620-17-7 3-ethylphenol 
• 77-78-1 dimethyl sulfate 
• 64-17-5 ethanol 
• 100-66-3 methoxybenzene 
• 353-36-6 1-fluoroethane 
• 75-00-3 chloroethane 
• 626-20-0 3-methoxystyrene 
• 67-56-1 methanol 
• 58114-05-9 1-chloro-1-(3'-methoxyphenyl)ethane 
• 768-70-7 1-ethynyl-3-methoxybenzene 
• 89691-63-4 1-(3-methoxy)-phenylethanol 
• 2845-89-8 1-chloro-3-methoxy-benzene 
• 557-20-0 diethylzinc 
• 591-31-1 3-methoxy-benzaldehyde 

Downstream Products

• 17299-34-2 3-ethylcyclohex-2-en-1-one 
• 64847-85-4 3-ethyl cyclohexanone 
• 1515-95-3 p-ethylanisole 
• 6161-69-9 2-ethyl-4-methoxybenzaldehyde 
• 88563-83-1 1-bromo-1-(3-methoxyphenyl)ethane 
• 86425-30-1 3-methoxy-N-(pyridin-2-yl)benzamide 
• 23308-82-9 (R)-(+)-1-(3-methoxyphenyl)-1-ethanol 
• 586-37-8 1-(3-Methoxyphenyl)ethanone 
• 41068-29-5 1-(2-ethyl-4-methoxyphenyl)ethanone 
• 50919-66-9 5-Ethyl-3-methoxy-phthalic acid 

Relevant articles and documents

Eleven amino acid glucagon-like peptide-1 receptor agonists with antidiabetic activity

Glucagon-like peptide 1 (GLP-1) is a 30 or 31 amino acid peptide hormone that contributes to the physiological regulation of glucose homeostasis and food intake. Herein, we report the discovery of a novel class of 11 amino acidGLP-1 receptor agonists. These peptides consist of a structurally optimized 9- mer, which is closely related to the N-terminal 9 amino acids ofGLP-1, linked to a substituted C-terminal biphenylalanine (BIP) dipeptide. SAR studies resulted in 11-mer GLP-1R agonists with similar in vitro potency to the native 30-mer. Peptides 21 and 22 acutely reduced plasma glucose excursions and increased plasma insulin concentrations in a mouse model of diabetes. These peptides also showed sustained exposures over several hours in mouse and dog models. The described 11-mer GLP-1 receptor agonists represent a new tool in further understanding GLP-1 receptor pharmacology that may lead to novel antidiabetic agents.

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.

Mechanism of the Bis(imino)pyridine-Iron-Catalyzed Hydromagnesiation of Styrene Derivatives

Iron-catalyzed hydromagnesiation of styrene derivatives offers a rapid and efficient method to generate benzylic Grignard reagents, which can be applied in a range of transformations to provide products of formal hydrofunctionalization. While iron-catalyzed methodologies exist for the hydromagnesiation of terminal alkenes, internal alkynes, and styrene derivatives, the underlying mechanisms of catalysis remain largely undefined. To address this issue and determine the divergent reactivity from established cross-coupling and hydrofunctionalization reactions, a detailed study of the bis(imino)pyridine iron-catalyzed hydromagnesiation of styrene derivatives is reported. Using a combination of kinetic analysis, deuterium labeling, and reactivity studies as well as in situ 57Fe M?ssbauer spectroscopy, key mechanistic features and species were established. A formally iron(0) ate complex [iPrBIPFe(Et)(CH2a?CH2)]- was identified as the principle resting state of the catalyst. Dissociation of ethene forms the catalytically active species which can reversibly coordinate the styrene derivative and mediate a direct and reversible β-hydride transfer, negating the necessity of a discrete iron hydride intermediate. Finally, displacement of the tridentate bis(imino)pyridine ligand over the course of the reaction results in the formation of a tris-styrene-coordinated iron(0) complex, which is also a competent catalyst for hydromagnesiation.

Homogeneous Palladium-Catalyzed Transfer Hydrogenolysis of Benzylic Alcohols Using Formic Acid as Reductant

We report the first homogeneous palladium-based transfer hydrogenolysis of benzylic alcohols using an in situ formed palladium-phosphine complex and formic acid as reducing agent. The reaction requires a catalyst loading as low as only 1 mol % of palladium and just a slight excess of reductant to obtain the deoxygenated alkylarenes in good to excellent yields. Besides demonstrating the broad applicability for primary, secondary and tertiary benzylic alcohols, a reaction intermediate could be identified. Additionally, it could be shown that partial oxidation of the applied phosphine ligand was beneficial for the course of the reaction, presumably by stabilizing the active catalyst. Reaction profiles and catalyst poisoning experiments were used to characterize the catalyst, the results of which indicate a homogeneous metal complex as the active species.