4442-79-9

Basic information

• Product Name: 2-Cyclohexylethanol
• Synonyms: 2-Cyclohexyl-1-ethanol;2-Cyclohexylethanol,(2-Hydroxyethyl)cyclohexane;2-CYCLOHEXYLETHANOL FOR SYNTHESIS;(2-HYDROXYETHYL)CYCLOHEXANE;2-CYCLOHEXYLETHANOL;2-CYCLOHEXANEETHANOL;CYCLOHEXANEETHANOL;CYCLOHEXANETHANOL
• CAS NO: 4442-79-9
• Molecular Formula: C₈H₁₆O
• Molecular Weight: 128.21
• EINECS: 224-672-1
• Product Categories: Alkohols;Industrial/Fine Chemicals
• Mol File: 4442-79-9.mol

Chemical Properties

• Melting Point: -20 °C
• Boiling Point: 206-207 °C745 mm Hg(lit.)
• Flash Point: 188 °F
• Appearance: clear colourless liquid
• Density: 0.919 g/mL at 25 °C(lit.)
• Vapor Pressure: 0.0508mmHg at 25°C
• Refractive Index: n20/D 1.465(lit.)
• Storage Temp.: Store below +30°C.
• PKA: 15.19±0.10(Predicted)
• Explosive Limit: 0.9-6.3%(V)
• Water Solubility: insoluble
• BRN: 1848152
• CAS DataBase Reference: 2-Cyclohexylethanol(CAS DataBase Reference)
• NIST Chemistry Reference: 2-Cyclohexylethanol(4442-79-9)
• EPA Substance Registry System: 2-Cyclohexylethanol(4442-79-9)

Safety Data

• Hazard Codes: Xn
• Statements: 21/22
• Safety Statements: 26-28-36/37/39
• WGK Germany: 3
• RTECS: KK3528000
• TSCA: Yes
• Hazardous Substances Data: 4442-79-9(Hazardous Substances Data)

Usage

Uses

Used in Chemical Synthesis:
2-Cyclohexylethanol is used as a building block for the synthesis of various chemical compounds due to its unique structure and reactivity. It is particularly useful in the green preparation of oxidative esterification of primary alcohols, which is an environmentally friendly method of producing esters from primary alcohols.
Used in Pharmaceutical Industry:
In the pharmaceutical industry, 2-Cyclohexylethanol can be used as a starting material for the synthesis of various drugs and drug intermediates. Its unique structure allows for the creation of novel compounds with potential therapeutic applications.
Used in Fragrance Industry:
Due to its pleasant odor, 2-Cyclohexylethanol can also be used as a component in the fragrance industry, where it can contribute to the development of new and unique scents for perfumes, colognes, and other scented products.
Used in Green Chemistry:
2-Cyclohexylethanol is used as a key component in green chemistry processes, specifically in the oxidative esterification of primary alcohols. This method is considered environmentally friendly and sustainable, as it reduces waste and harmful byproducts during the esterification process.

Preparation

By catalytic hydrogenation of phenylethyl alcohol under pressure (Arctander, 1969).

Synthesis Reference(s)

Journal of the American Chemical Society, 108, p. 1325, 1986 DOI: 10.1021/ja00266a049

InChI:InChI=1/C8H16O/c9-7-6-8-4-2-1-3-5-8/h8-9H,1-7H2

Upstream product

• 75-21-8 oxirane 
• 110-82-7 cyclohexane 
• 931-51-1 cyclohexylmagnesiumchloride 
• 3007-12-3 dicyclohexylmagnesium 
• 60-29-7 diethyl ether 
• 931-50-0 cyclohexylmagnesium bromide 
• 71-43-2 benzene 
• 5452-75-5 ethyl 2-cyclohexylacetate 
• 101-97-3 Ethyl 2-phenylethanoate 
• 103-45-7 acetic acid phenethyl ester 
• 3197-68-0 2-(1-Cyclohexenyl)ethanol 
• 5631-96-9 2-(2-chloroethoxy)-tetrahydro-2H-pyrane 
• 766-05-2 cyclohexane carbonitrile 
• 108-05-4 vinyl acetate 

Downstream Products

• 1647-26-3 1-bromo-2-cyclohexylethane 
• 101087-38-1 3,5-dinitro-benzoic acid-(2-cyclohexyl-ethyl ester) 
• 80203-35-6 (2-iodoethyl)cyclohexane 
• 5664-21-1 cyclohexylacetaldehyde 
• 103983-46-6 (2-cyclohexyl-ethyl)-vinyl ether 
• 41010-09-7 3-cyclohexylpropionitrile 
• 21722-83-8 cyclohexyl ethyl acetate 
• 39753-13-4 Allyl-thiophosphoramidic acid O-(2-cyclohexyl-ethyl) ester O'-(2,2-dichloro-vinyl) ester 
• 85003-02-7 2-(2-Cyclohexyl-ethoxy)-5-nitro-pyridine 
• 85002-75-1 1-(2-Cyclohexyl-ethoxy)-4-nitro-benzene 
• 21336-37-8 2-cyclohexylethyl tosylate 
• 16423-32-8 4-Brom-benzolsulfonsaeure-<2-cyclohexyl-aethylester> 
• 252990-02-6 2-cyclohexylethyl N-Boc-3-(4-piperidinepropionyl)-(R)-(-)-nipecotyl-[(S)-3-amino-3-(3-pyridyl)]propionate 
• 316378-07-1 2-(cyclohexyl)ethyl benzenesulfenate 

Relevant articles and documents

A METHOD FOR PRODUCING VINYLCYCLOALKANES COMPOUNDS

The present invention relates to a method for producing vinylcycloalkanes compounds represented by the general formula (5) highly selectively and economically, which comprises hydrogenation and dehydration. Hydrogenation step: hydrogenating the compounds represented by the general formula (1) or/and (2) or/and (3) or/and (4) with hydrogen to prepare the corresponding primary or secondary alcohols in the presence of hydrogenation catalyst with min. 0.1 part by wight. Dehydration step: dehydrating the corresponding primary or secondary alcohols prepared by the above-mentioned hydrogenation step to prepare vinylcycloalkanes compounds represented by the general formula (5) in the presence of dehydration catalyst. R 1 -CH2-CH2-OH (1) Wherein R 1 of the general formula (1)~(4) is hydrocarbyl (hydrocarbon functional group) having aromatic rings. R 2 -CH=CH2(5) Wherein R 2 of the general formula (5) is cycloalkyl or cycloalkyl-substituted alkyl.

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.

HYDROGENATION OF CARBONYLS WITH TETRADENTATE PNNP LIGAND RUTHENIUM COMPLEXES

The present invention relates to catalytic hydrogenation processes, using Ru complexes with tetradentate ligands of formula L in hydrogenation processes for the reduction of ketone, aldehyde, ester or lactone into the corresponding alcohol or diol respectively. The described processes use a ruthenium complex of the formula (1) as defined below, and where the ligand (L) is defined by the Markush formula shown above.

Visible-Light-Mediated Aerobic Oxidation of Organoboron Compounds Using in Situ Generated Hydrogen Peroxide

A simple and general visible-light-mediated oxidation of organoboron compounds has been developed with rose bengal as the photocatalyst, substoichiometric Et3N as the electron donor, as well as air as the oxidant. This mild and metal-free protocol shows a broad substrate scope and provides a wide range of aliphatic alcohols and phenols in moderate to excellent yields. Notably, the robustness of this method is demonstrated on the stereospecific aerobic oxidation of organoboron compounds.

Carbon chain shape selectivity by the mouse olfactory receptor OR-I7

The rodent OR-I7 is an olfactory receptor exemplar activated by aliphatic aldehydes such as octanal. Normal alkanals shorter than heptanal bind OR-I7 without activating it and hence function as antagonists in vitro. We report a series of aldehydes designed to probe the structural requirements for aliphatic ligand chains too short to meet the minimum approximate 6.9 ? length requirement for receptor activation. Experiments using recombinant mouse OR-I7 expressed in heterologous cells show that in the context of short aldehyde antagonists, OR-I7 prefers binding aliphatic chains without branches, though a single methyl on carbon-3 is permitted. The receptor can accommodate a surprisingly large number of carbons (e.g. ten in adamantyl) as long as the carbons are part of a conformationally constrained ring system. A rhodopsin-based homology model of mouse OR-I7 docked with the new antagonists suggests that small alkyl branches on the alkyl chain sterically interfere with the hydrophobic residues lining the binding site, but branch carbons can be accommodated when tied back into a compact ring system like the adamantyl and bicyclo[2.2.2]octyl systems.

Ruthenium-Catalyzed Deoxygenative Hydroboration of Carboxylic Acids

An efficient deoxygenative hydroboration of carboxylic acids to alkyl boronate esters under mild reaction condition is reported. Both aromatic and aliphatic carboxylic acids exhibited excellent reactivities with minimal catalyst load of 0.1 mol% and reactions occurred under neat conditions. This catalytic transformation selectively provides alkyl boronate esters, which can be conveniently hydrolyzed to obtain the corresponding alcohols. Remarkably, this reduction reaction proceeds with the liberation of molecular hydrogen.

Palladium-Catalyzed Reductive Insertion of Alcohols into Aryl Ether Bonds

Palladium on carbon catalyzes C?O bond cleavage of aryl ethers (diphenyl ether and cyclohexyl phenyl ether) by alcohols (R?OH) in H2. The aromatic C?O bond is cleaved by reductive solvolysis, which is initiated by Pd-catalyzed partial hydrogenation of one phenyl ring to form an enol ether. The enol ether reacts rapidly with alcohols to form a ketal, which generates 1-cyclohexenyl?O?R by eliminating phenol or an alkanol. Subsequent hydrogenation leads to cyclohexyl?O?R.

Robust cobalt oxide catalysts for controllable hydrogenation of carboxylic acids to alcohols

The selective catalytic hydrogenation of carboxylic acids is an important process for alcohol production, while efficient heterogeneous catalyst systems are still being explored. Here, we report the selective hydrogenation of carboxylic acids using earth-abundant cobalt oxides through a reaction-controlled catalysis process. The further reaction of the alcohols is completely hindered by the presence of carboxylic acids in the reaction system. The partial reduction of cobalt oxides by hydrogen at designated temperatures can dramatically enhance the catalytic activity of pristine samples. A wide range of carboxylic acids with a variety of functional groups can be converted to the corresponding alcohols at a yield level applicable to large-scale production. Cobalt monoxide was established as the preferred active phase for the selective hydrogenation of carboxylic acids.

Reductive fractionation of woody biomass into lignin monomers and cellulose by tandem metal triflate and Pd/C catalysis

A catalytic process for the upgrading of woody biomass into mono-aromatics, hemi-cellulose sugars and a solid cellulose-rich carbohydrate residue is presented. Lignin fragments are extracted from the lignocellulosic matrix by cleavage of ester and ether linkages between lignin and carbohydrates by the catalytic action of homogeneous Lewis acid metal triflates in methanol. The released lignin fragments are converted into lignin monomers by the combined catalytic action of Pd/C and metal triflates in hydrogen. The mechanism of ether bond cleavage is investigated by lignin dimer models (benzyl phenyl ether, guaiacylglycerol-β-guaiacyl ether, 2-phenylethyl phenyl ether and 2-phenoxy-1-phenylethanol). Metal triflates are involved in cleaving not only ester and ether linkages between lignin and the carbohydrates but also β-O-4 ether linkages within the aromatic lignin structure. Metal triflates are more active for β-O-4 ether bond cleavage than Pd/C. On the other hand, Pd/C is required for cleaving α-O-4, 4-O-5 and β-β linkages. Insight into the synergy between Pd/C and metal triflates allowed optimizing the reductive fractionation process. Under optimized conditions, 55 wt% mono-aromatics-mainly alkylmethoxyphenols-can be obtained from the lignin fraction (23.8 wt%) of birch wood in a reaction system comprising birch wood, methanol and small amounts of Pd/C and Al(III)-triflate as catalysts. The promise of scale-up of this process is demonstrated.

One-Carbon Homologation of Primary Alcohols and the Reductive Homologation of Aldehydes Involving a Jocic-Type Reaction

(Trichloromethyl)carbinols, which are formed in one operation from either alcohols or aldehydes, can be converted into primary alcohols in a Jocic-type reaction involving LiBH4. The net result is a convenient two-step, one-carbon homologation of primary alcohols or a reductive one-carbon homologation of aldehydes featuring a broad substrate scope. The method is step-economical, and it nicely complements established one-carbon homologation strategies. (Trichloromethyl)carbinols, which are formed in one operation from either alcohols or aldehydes, can be converted into primary alcohols in a Jocic-type reaction involving LiBH4. The net result is a convenient two-step, one-carbon homologation of primary alcohols or a reductive one-carbon homologation of aldehydes featuring a broad substrate scope.