1123-86-0

Basic information

• Product Name: CYCLOHEXYL ETHYL KETONE
• Synonyms: Ethyl cyclohexyl ketone;Ketone, cyclohexyl ethyl;CYCLOHEXYL ETHYL KETONE;1-CYCLOHEXYL-1-PROPANONE;1-cyclohexylpropan-1-one;CYCLOHEXYLPROPANONE;propionylcyclohexane;Propanoylcyclohexane
• CAS NO: 1123-86-0
• Molecular Formula: C₉H₁₆O
• Molecular Weight: 140.22
• EINECS: 214-380-2
• Mol File: 1123-86-0.mol

Chemical Properties

• Boiling Point: 196°C (estimate)
• Flash Point: 74.5°C
• Appearance: /
• Density: 0,91 g/cm3
• Vapor Pressure: 0.408mmHg at 25°C
• Refractive Index: 1.4530
• Storage Temp.: 2-8°C
• Solubility: Soluble in organic solvents.
• CAS DataBase Reference: CYCLOHEXYL ETHYL KETONE(CAS DataBase Reference)
• NIST Chemistry Reference: CYCLOHEXYL ETHYL KETONE(1123-86-0)
• EPA Substance Registry System: CYCLOHEXYL ETHYL KETONE(1123-86-0)

Safety Data

• Hazardous Substances Data: 1123-86-0(Hazardous Substances Data)

Usage

Uses

Used in Organic Synthesis Industry:
Cyclohexyl ethyl ketone is used as a key intermediate for the synthesis of a wide range of organic compounds. Its unique structure allows it to participate in various chemical reactions, making it a valuable building block in the creation of pharmaceuticals, agrochemicals, and other specialty chemicals.
Used in Pharmaceutical Industry:
In the pharmaceutical industry, cyclohexyl ethyl ketone is utilized as a starting material for the synthesis of various drug molecules. Its ability to form different chemical bonds and participate in reactions makes it an essential component in the development of new medications and therapies.
Used in Agrochemical Industry:
Cyclohexyl ethyl ketone also finds application in the agrochemical sector, where it is used as an intermediate for the synthesis of pesticides, herbicides, and other crop protection agents. Its versatility in organic synthesis enables the production of effective and targeted agrochemicals to improve crop yields and protect against pests.
Used in Specialty Chemicals Industry:
In the specialty chemicals industry, cyclohexyl ethyl ketone is employed as a precursor for the synthesis of various specialty chemicals, such as fragrances, dyes, and other high-value compounds. Its unique properties and reactivity contribute to the development of innovative and high-performing specialty products.

InChI:InChI=1/C9H16O/c1-2-9(10)8-6-4-3-5-7-8/h8H,2-7H2,1H3

Upstream product

• 17566-51-7 N,N-dimethylcyclohexanecarboxamide 
• 1124-89-6 1-(α-Oxy-propyl)-cyclohexanol-(1) 
• 79-03-8 propionyl chloride 
• 110-83-8 cyclohexene 
• 144-62-7 oxalic acid 
• 557-20-0 diethylzinc 
• 2719-27-9 cyclohexanylcarbonyl chloride 
• 1655-03-4 1-cyclohex-1-enyl-propan-1-one 
• 61173-89-5 1-<1,1-Bis-(phenylthio)-propyl>-cyclohexanol 
• 62672-77-9 1-(cyclohexen-1-yl)-2-propen-1-one 
• 17715-01-4 1-Hydroperoxy-1-cyclohexyl-propin-⁽²⁾ 
• 123-38-6 propionaldehyde 
• 802294-64-0 propionic acid 
• 74-85-1 ethene 

Downstream Products

• 33204-54-5 (+/-)-2-cyclohexyl-butan-2-ol 
• 102176-46-5 bis-(1-cyclohexyl-propylidene)-hydrazine 
• 60092-79-7 4-(1-cyclohexyl-propenyl)-morpholine 
• 57387-61-8 Z-Diethyl-(1-cyclohexyl-1-propenyloxy)-boran 
• 141548-68-7 (S)-5-((S)-1-Cyclohexyl-1-hydroxy-propyl)-4-methoxymethoxy-5H-furan-2-one 
• 76436-98-1 (Z)-1-cyclohexyl-1-(trimethylsilyloxy)-1-propene 
• 76437-07-5 (E)-1-cyclohexyl-1-(trimethylsiloxy)-1-propene 
• 38636-38-3 (R)-1-cyclohexylpropan-1-ol 
• 110529-28-7 (S)-1-cyclohexylpropan-1-ol 
• 72449-22-0 (2RS,3SR)-1-cyclohexyl-3-hydroxy-2-methyl-3-phenylpropan-1-one 
• 72449-22-0 (2SR,3SR)-1-cyclohexyl-3-hydroxy-2-methyl-3-phenylpropan-1-one 
• 119924-84-4 4-cyclohexyl-3-methyl-4-oxobutanoic acid methyl ester 
• 4361-29-9 3-cyclohexylpropanamide 
• 609772-40-9 (S)-4-Benzyl-3-[1-cyclohexyl-prop-(E)-ylideneamino]-oxazolidin-2-one 

Relevant articles and documents

Highly Efficient Oxidation of Secondary Alcohols to Ketones Catalyzed by Manganese Complexes of N4 Ligands with H2O2

The manganese complex Mn(S-PMB)(CF3SO3)2 was proven to be highly efficient in the catalytic oxidation of several benzylic and aliphatic secondary alcohols with H2O2 as the oxidant and acetic acid as the additive. A maximum turnover number of 4700 was achieved in the alcohol oxidation. In addition, the Hammett analysis unveiled the electrophilic nature of this manganese catalyst with N4 ligand. (Chemical Equation Presented).

Synthesis of a polymer–ruthenium complex Ru(pbbp)(pydic) and its catalysis in the oxidation of secondary alcohols with TBHP as oxidant

A polymer–ruthenium complex Ru(pbbp)(pydic) was synthesized from the reaction of poly-2,6-bis(benzimidazolyl)pyridine (pbbp) with RuCl3 and disodium pyridine-2,6-dicarboxylate (pydic). The Ru(pbbp)(pydic) was characterized thoroughly by spectroscopic methods. ICP analysis revealed that the percentage of complexation of 2,6-bis(benzimidazolyl)pyridine unit in pbbp was about 83%. The complex was tested as a heterogeneous catalyst for the oxidation of secondary alcohols to their corresponding carbonyl compounds in solvent-free conditions using aqueous tert-butyl hydroperoxide as oxidant. The developed catalytic system exhibited high activity and broad functional group compatibility, allowing a variety of secondary alcohols, including substituted secondary benzylic alcohols and secondary aliphatic ones, to be oxidized to the corresponding ketones in high yields. This Ru(pbbp)(pydic) could be recycled for several times, but it dissolved in part in the reaction mixture during the catalytic run leading to gradual deactivation of the catalyst with repeated runs.

Aerobic oxidation of secondary alcohols using NHPI and iron salt as catalysts at room temperature

Aerobic oxidation of various alcohols has been accomplished by using a novel catalytic system, N-hydroxyphthalimide (NHPI) combined with Fe(NO 3)3·9H2O. Secondary alcohols, especially benzylic and aliphatic alcohols, were smoothly transformed into corresponding ketones with up to 92% yields at room temperature under one atmosphere pressure of oxygen. The influences of reaction conditions such as solvent, different metal catalyst, catalyst loading and the structure of alcohols on the promotion effect were studied. And a possible radical mechanism for the oxidation of secondary alcohols in Fe(NO3)3·9H 2O/NHPI/O2 system was proposed.

Chelation-Assisted C-H and C-C Bond Activation of Allylic Alcohols by a Rh(I) Catalyst under Microwave Irradiation

Chelation-assisted Rh(I)-catalyzed ketone synthesis from allylic alcohols and alkenes through C-H and C-C bond activations under microwave irradiation was developed. Aldimine is formed via olefin isomerization of allyl alcohol under Rh(I) catalysis and condensation with 2-amino-3-picoline, followed by continuous C-H and C-C bond activations to produce a dialkyl ketone. The addition of piperidine accelerates the reaction rate by promoting aldimine formation under microwave conditions.

Efficient oxidation of secondary alcohols to ketones by NaOCl catalyzed by salen-Mn(III)/NBS

An efficient catalytic system salen-Mn(III)/NBS for oxidation of secondary alcohols to ketones by inexpensive and readily available oxidizing agent NaOCl has been developed. The process resulted in good to excellent yields under the action of 2 mol % of salen-Mn(III) and 13 mol % of NBS at room temperature. However, such system was not efficient in oxidation of secondary benzyl alcohols with a strong electronicdonating substituent attached to the benzene ring due to bromination of the alcohols.

Pd-H from Pd/C and triethylamine: Implications in palladium catalysed reactions involving amines

The palladium hydride-iminium complex generated from Pd/C and triethylamine catalyses the isomerisation of allylic alcohols into carbonyl compounds, and Pd/C catalyses the conjugate reduction of activated double bonds using triethylamine as the source of the two newly incorporated hydrogen atoms via the same complex.

Modular counter-Fischer?indole synthesis through radical-enolate coupling

A single-electron transfer mediated modular indole formation reaction from a 2-iodoaniline derivative and a ketone has been developed. This transition-metal-free reaction shows a broad substrate scope and unconventional regioselectivity trends. Moreover, important functional groups for further transformation are tolerated under the reaction conditions. Density functional theory studies reveal that the reaction proceeds by metal coordination, which converts a disfavored 5-endo-trig cyclization to an accessible 7-endo-trig process.

Aromatic compound hydrogenation and hydrodeoxygenation method and application thereof

The invention belongs to the technical field of medicines, and discloses an aromatic compound hydrogenation and hydrodeoxygenation method under mild conditions and application of the method in hydrogenation and hydrodeoxygenation reactions of the aromatic compounds and related mixtures. Specifically, the method comprises the following steps: contacting the aromatic compound or a mixture containing the aromatic compound with a catalyst and hydrogen with proper pressure in a solvent under a proper temperature condition, and reacting the hydrogen, the solvent and the aromatic compound under the action of the catalyst to obtain a corresponding hydrogenation product or/and a hydrodeoxygenation product without an oxygen-containing substituent group. The invention also discloses specific implementation conditions of the method and an aromatic compound structure type applicable to the method. The hydrogenation and hydrodeoxygenation reaction method used in the invention has the advantages of mild reaction conditions, high hydrodeoxygenation efficiency, wide substrate applicability, convenient post-treatment, and good laboratory and industrial application prospects.

Multiple Mechanisms Mapped in Aryl Alkyl Ether Cleavage via Aqueous Electrocatalytic Hydrogenation over Skeletal Nickel

We present here detailed mechanistic studies of electrocatalytic hydrogenation (ECH) in aqueous solution over skeletal nickel cathodes to probe the various paths of reductive catalytic C-O bond cleavage among functionalized aryl ethers relevant to energy science. Heterogeneous catalytic hydrogenolysis of aryl ethers is important both in hydrodeoxygenation of fossil fuels and in upgrading of lignin from biomass. The presence or absence of simple functionalities such as carbonyl, hydroxyl, methyl, or methoxyl groups is known to cause dramatic shifts in reactivity and cleavage selectivity between sp3 C-O and sp2 C-O bonds. Specifically, reported hydrogenolysis studies with Ni and other catalysts have hinted at different cleavage mechanisms for the C-O ether bonds in α-keto and α-hydroxy β-O-4 type aryl ether linkages of lignin. Our new rate, selectivity, and isotopic labeling results from ECH reactions confirm that these aryl ethers undergo C-O cleavage via distinct paths. For the simple 2-phenoxy-1-phenylethane or its alcohol congener, 2-phenoxy-1-phenylethanol, the benzylic site is activated via Ni C-H insertion, followed by beta elimination of the phenoxide leaving group. But in the case of the ketone, 2-phenoxyacetophenone, the polarized carbonyl πsystem apparently binds directly with the electron rich Ni cathode surface without breaking the aromaticity of the neighboring phenyl ring, leading to rapid cleavage. Substituent steric and electronic perturbations across a broad range of β-O-4 type ethers create a hierarchy of cleavage rates that supports these mechanistic ideas while offering guidance to allow rational design of the catalytic method. On the basis of the new insights, the usage of cosolvent acetone is shown to enable control of product selectivity.

Selective hydrogenation of aromatic compounds using modified iridium nanoparticles

Till now, Ionic liquid-stabilized metal nanoparticles were investigated as catalytic materials, mostly in the hydrogenation of simple substrates like olefins or arenes. The adjustable hydrogenation products of aromatic compounds, including quinoline and relevant compounds, aromatic nitro compounds, aromatic ketones as well as aromatic aldehydes, are always of special interest, since they provide more choices for additional derivatization. Iridium nanoparticles (Ir NPs) were synthesized by the H2 reduction in imidazolium ionic liquid. TEM indicated that the Ir NPs is worm-like shape with the diameter around 12.2?nm and IR confirmed the modification of phosphine-functionalized ionic liquids (PFILs) to the Ir NPs. With the variation of the modifier, solvent and reaction temperature, substrate like quinoline and relevant compounds, aromatic nitro compounds, aromatic ketones as well as aromatic aldehydes could be hydrogenated by Ir NPs with interesting adjustable catalytic activity and chemoselectivity. Ir NPs modified by PFILs are simple and efficient catalysts in challenging chemoselective hydrogenation of quinoline and relevant compounds, aromatic nitro compounds, aromatic ketones as well as aromatic aldehydes. The activity and chemoselectivity of the Ir NPs could be obviously impacted or adjusted by altering the modifier, solvent and reaction temperature.