590-67-0

Basic information

• Product Name: 11 -Methylcyclohexanol
• Synonyms: 1-Hydroxy-1-methylcyclohexane;1-Methyl-1-cyclohexanol;1-Methylcyclohexyl alcohol;NSC1247
• CAS NO: 590-67-0
• Molecular Formula: C₇H₁₄O
• Molecular Weight: 114.18
• EINECS: 209-688-9
• Mol File: 590-67-0.mol
• Article Data: 146

Chemical Properties

• Melting Point: 26℃
• Boiling Point: 156.999 °C at 760 mmHg
• Flash Point: 67.778 °C
• Appearance: clear colorless to light yellow liquid
• Density: 0.937 g/cm³
• Refractive Index: 1.459-1.461
• PKA: 15.38±0.20(Predicted)
• CAS DataBase Reference: 11 -Methylcyclohexanol(CAS DataBase Reference)
• NIST Chemistry Reference: 11 -Methylcyclohexanol(590-67-0)
• EPA Substance Registry System: 11 -Methylcyclohexanol(590-67-0)

Safety Data

• Hazard Codes: Xn:Harmful
• Statements: R20/21/22:; R36/37/38:
• Safety Statements: S26:; S36/37/39:; S38:
• Hazardous Substances Data: 590-67-0(Hazardous Substances Data)

Usage

General Description

11-Methylcyclohexanol is a colorless, organic compound with the chemical formula C7H14O. It is a secondary alcohol with a distinct odor and is commonly used in the production of perfumes and other fragrance products. This chemical is also used as a solvent and as an intermediate in the synthesis of other chemicals. 11-Methylcyclohexanol can be synthesized through the hydration of 1-methylcyclohexene or by the reduction of 1-methylcyclohexanone. It is flammable and may cause irritation to the eyes, skin, and respiratory system upon exposure. Additionally, it should be handled and stored in a well-ventilated area and away from heat, sparks, and open flames.

InChI:InChI=1/C7H14O/c1-7(8)5-3-2-4-6-7/h8H,2-6H2,1H3

Upstream product

• 1713-33-3 1,2-epoxy-1-methylcyclohexane 
• 108-94-1 cyclohexanone 
• 35739-70-9 dimethyldichlorotitanium(IV) 
• 121416-55-5 (+/-)-2-(4-bromobutyl)-2-methyloxirane 
• 60-29-7 diethyl ether 
• 56-23-5 tetrachloromethane 
• 14977-61-8 chromyl chloride 
• 82166-21-0 methyl cyclohexane 
• 7782-77-6 cis-nitrous acid 
• 3218-02-8 cyclohexylmethylamine 
• 4952-03-8 1-methylcyclohexane hydroperoxide 
• 64-19-7 acetic acid 
• 931-77-1 1-bromo-1-methylcyclohexane 
• 591-49-1 1-methylcyclohex-1-ene 

Downstream Products

• 100879-09-2 piperidino-acetic acid-(1-methyl-cyclohexylamide) 
• 100534-28-9 tert-butyl-(1-methyl-cyclohexyl)-peroxide 
• 591-49-1 1-methylcyclohex-1-ene 
• 6526-78-9 1-methyl-1-cyclohexylamine 
• 3338-03-2 2-methyl-4,5,6,7-tetrahydro-3H-azepine 
• 4952-03-8 1-methylcyclohexane hydroperoxide 
• 36413-13-5 1-Methylcyclohexyl nitrite 
• 87-83-2 pentabromotoluene 
• 931-78-2 1-chloro-1-methylcyclohexane 
• 931-77-1 1-bromo-1-methylcyclohexane 
• 35812-26-1 dithiocarbonic acid O-(1-methyl-cyclohexyl ester)-S-methyl ester 
• 1192-37-6 methylenecyclohexane 
• 78-79-5 isoprene 
• 16737-30-7 1-acetoxy-1-methyl-cyclohexane 

Relevant articles and documents

Acid-Catalyzed Hydrolysis of Bridged Bi- and Tricyclic Compounds. 25. Comparison of the Hydrations of 2-Methyl-2-norbornene and 2-Methylenenorbornane with Those of 1-Methylcyclohexene and Methylenecyclohexane

Hydration rates of 2-methyl-2-norbornene, 2-methylenenorbornane, 1-methylcyclohexene, and methylenecyclohexane were measured spectrophotometrically in aqueous perchloric acid.The activation parameters and solvent deuterium isotope effects are in all cases in agreement with the slow proton transfer to an olefinic carbon atom.The free energy diagrams show that the Gibbs energy of the transition state of protonation (hydration) is higher for methylenecycloalkanes than for methylcycloalkenes.The energy difference is small (0.8 kJ mol-1) in the case of the bicyclic olefins and large (11.5 kJ mol-1) in the case of the monocyclic olefins mentioned.Thus, no marked difference in the energies of the transition states caused by a possible distortion of the ?-orbitals of 2-methyl-2-norbornene can be seen in the hydrations of the bicyclic olefins.An explanation for the latter large difference is evidently a change of conformation during the protonation of 1-methylcyclohexene, which possibly also causes an exceptionally low isotope effect (kH/kD=1.13).

Hydrogen-atom and oxygen-atom transfer reactivities of iron(

A series of iron(ii) complexes with the general formula [FeII(L2-Qn)(L)]n+ (n = 1, L = F?, Cl?; n = 2, L = NCMe, H2O) have been isolated and characterized. The X-ray crystallographic data reveals that

Cationic nickel(II) pyridinophane complexes: Synthesis, structures and catalytic activities for C-H oxidation

A series of nickel(II) pyridinophane complexes were synthesized and characterized by X-ray crystallographic analysis. Their IR spectra supported the existence of mononuclear nickel(II) complexes in solution. Furthermore, we conducted catalytic CH oxidation of cyclooctane with nickel(II) pyridinophanes as the catalysts. The activity of nickel(II) pyridinophanes was affected by steric hindrance around the nitrogen atoms.

Efficient alkane hydroxylation catalysis of nickel(ii) complexes with oxazoline donor containing tripodal tetradentate ligands

Tris(oxazolynylmethyl)amine TOAR(where R denotes the substituent groups on the fourth position of the oxazoline rings) complexes of nickel(ii) have been synthesized as catalyst precursors for alkane oxidation withmeta-chloroperoxybenzoic acid (m-CPBA). The molecular structures of acetato, nitrato,meta-chlorobenzoato and chlorido complexes with TOAMe2have been determined using X-ray crystallography. The bulkiness of the substituent groups R affects the coordination environment of the nickel(ii) centers, as has been demonstrated by comparison of the molecular structures of chlorido complexes with TOAMe2and TOAtBu. The nickel(ii)-acetato complex with TOAMe2is an efficient catalyst precursor compared with the tris(pyridylmethyl)amine (TPA) analogue. Oxazolynyl donors’ strong s-electron donating ability will enhance the catalytic activity. Catalytic reaction rates and substrate oxidizing position selectivity are controlled by the structural properties of the R of TOAR. Reaction of the acetato complex with TOAMe2andm-CPBA yields the corresponding acylperoxido species, which can be detected using spectroscopy. Kinetic studies of the decay process of the acylperoxido species suggest that the acylperoxido species is a precursor of an active species for alkane oxidation.