96-41-3

Basic information

• Product Name: Cyclopentanol
• Synonyms: CYCLOPENTANOL;CYCLOPENTYL ALCOHOL;HYDROXYCYCLOPENTANE;Cyclopentanol(RotationalformII);Cyclopentanol,99%;Cyclopentanol, 99% 500GR;CYCLOPENTANOL FOR SYNTHESIS 100 ML;Cyclopentanol 99%
• CAS NO: 96-41-3
• Molecular Formula: C₅H₁₀O
• Molecular Weight: 86.13
• EINECS: 202-504-8
• Product Categories: Pharmaceutical Intermediates;Alcohols;C2 to C6;Oxygen Compounds
• Mol File: 96-41-3.mol
• Article Data: 305

Chemical Properties

• Melting Point: -19 °C
• Boiling Point: 139-140 °C(lit.)
• Flash Point: 124 °F
• Appearance: Clear colorless to slightly yellow/Liquid
• Density: 0.949 g/mL at 25 °C(lit.)
• Refractive Index: n20/D 1.453(lit.)
• Storage Temp.: Flammables area
• PKA: 15.31±0.20(Predicted)
• Water Solubility: slightly soluble
• Stability: Stable. Flammable. Incompatible with strong oxidizing agents, acid chlorides, acid anhydrides.
• Merck: 14,2742
• BRN: 1900556
• CAS DataBase Reference: Cyclopentanol(CAS DataBase Reference)
• NIST Chemistry Reference: Cyclopentanol(96-41-3)
• EPA Substance Registry System: Cyclopentanol(96-41-3)

Safety Data

• Hazard Codes: Xi
• Statements: 10-36/37/38
• Safety Statements: 16-36-26
• RIDADR: UN 2244 3/PG 3
• WGK Germany: 1
• TSCA: Yes
• HazardClass: 3
• PackingGroup: III
• Hazardous Substances Data: 96-41-3(Hazardous Substances Data)

Usage

Physical and chemical properties

Cyclopentanol is also known as hydroxy cyclopentane. It is colorless oily liquid. It has a special mildew smell. Relative molecular mass is 86.14. The relative density is 0.9478. Melting point is-19 ℃. Boiling point is 140.85 ℃, 56.4~57.4 ℃ (4.533 × 103Pa), 53 ℃ (1.333 × 103Pa). The refractive index is 1.4530. The flash point is 51℃. It is Slightly soluble in water, soluble in alcohol, ether and acetone. It can form azeotropic mixture with water, the content of product is 42% at this time, the azeotropic point is 96.3℃. ? Figure 1 is the structural formula of cyclopentanol spherical [Uses] Cyclopentanol is mainly used for the production of pharmaceutical raw materials, dyes, perfumes. It is also used for solvent of drugs and spices. [Preparation method] under the effect of barium hydroxide, adipic acid goes through dry distillation to get cyclopentanone, and then with lithium aluminum tetrahydrocannabinol occurs hydrogenation to obtain cyclopentanol in ether. This information is edited by lookchem Xiaonan (2016-12-03).

Chemical properties

It is colorless aroma viscous liquid. It is soluble in alcohol, slightly soluble in water.

Uses

Different sources of media describe the Uses of 96-41-3 differently. You can refer to the following data:
1. (1) Cyclopentanol is used in medicine, dyes preparation and spices, it can also used for solvent of drugs and spices.? (2) It is used for organic synthesis intermediates, it is used for pharmaceuticals, dyes and spices production, it is also used for solvent of drugs and spices. (3) It is used as spice and medicine solvent and dye intermediates. (4) It is used in medicine, dyes and perfumes production, it is also used for solvent of drugs and spices.
2. A versatile compound used as a building block, intermediate, and solvent.
3. Cyclopentanol is a versatile compound used as a building block, intermediate and solvent.
4. Cyclopentanol can be used as:An alkylating agent in the preparation of alkylated aromatic compounds using Fe3+-montmorillonite catalyst via Friedel–Crafts alkylation reaction.A reactant in the acylation of alcohols with an acid anhydride or acid chloride.A substrate in the synthesis of high-density polycyclic aviation fuel by the Guerbet reaction.

Preparation method

Under the effect of sodium hydroxide, adipic acid goes through dry distillation to obtain cyclopentanone, cyclopentanone and lithium aluminum tetrahydrocannabinol ether occurs hydrogenation to get it in diethyl at room temperature. Or in the presence of copper-chromium catalyst at 150℃, 150 atmospheric pressure cyclopentanone occurs hydrogenation or in the presence of platinum catalyst in 0.2-0.3MPa occurs hydrogenation to obtain crude product, crude distillation derives products. Material consumption fixed: adipic 2500kg/t, barium 900kg/t.

Chemical Properties

colourless liquid

Definition

ChEBI: The simplest member of the class of cyclopentanols bearing a single hydroxy substituent. The parent of the class of cyclopentanols.

General Description

A colorless viscous liquid with a pleasant odor. Slightly less dense than water. Flash point 124°F. Vapors heavier than air. Used to make perfumes and pharmaceuticals.

Reactivity Profile

Cyclopentanol is an alcohol. Flammable and/or toxic gases are generated by the combination of alcohols with alkali metals, nitrides, and strong reducing agents. They react with oxoacids and carboxylic acids to form esters plus water. Oxidizing agents convert them to aldehydes or ketones. Alcohols exhibit both weak acid and weak base behavior. They may initiate the polymerization of isocyanates and epoxides.

Health Hazard

May cause toxic effects if inhaled or absorbed through skin. Inhalation or contact with material may irritate or burn skin and eyes. Fire will produce irritating, corrosive and/or toxic gases. Vapors may cause dizziness or suffocation. Runoff from fire control or dilution water may cause pollution.

Fire Hazard

HIGHLY FLAMMABLE: Will be easily ignited by heat, sparks or flames. Vapors may form explosive mixtures with air. Vapors may travel to source of ignition and flash back. Most vapors are heavier than air. They will spread along ground and collect in low or confined areas (sewers, basements, tanks). Vapor explosion hazard indoors, outdoors or in sewers. Runoff to sewer may create fire or explosion hazard. Containers may explode when heated. Many liquids are lighter than water.

InChI:InChI=1/C5H10O/c6-5-3-1-2-4-5/h5-6H,1-4H2

Upstream product

• 287-92-3 Cyclopentane 
• 930-28-9 cyclopentyl chloride 
• 4415-82-1 cyclobutanemethanol 
• 144-62-7 oxalic acid 
• 60-29-7 diethyl ether 
• 677-22-5 tert-butylmagnesium chloride 
• 120-92-3 cyclopentanone 
• 64-17-5 ethanol 
• 3475-65-8 thiamine triphosphate 
• 1003-03-8 Cyclopentamine 
• 285-67-6 Cyclopentene oxide 
• 21746-87-2 5-bromo-1,2-epoxypentane 
• 23985-40-2 tricyclopentylborane 
• 1528-30-9 methylenecyclopentane 

Downstream Products

• 71172-31-1 3,5-dinitro-benzoic acid cyclopentyl ester 
• 959-69-3 Bernsteinsaeure-dicyclopentylester 
• 41215-40-1 N-cyclopentylcarboxamide 
• 137-43-9 Cyclopentyl bromide 
• 110-94-1 1,5-pentanedioic acid 
• 930-28-9 cyclopentyl chloride 
• 1556-18-9 cyclopentyl iodide 
• 61081-80-9 p-nitrobenzoate de cyclopentyle 
• 142-29-0 cyclopentene 
• 482-59-7 (+/-)-(4ar,4bt,9at,14at)-tetradecahydro-tripyrido[1,2-a;1',2'-c;3'',2''-e]pyrimidine 
• 933-05-1 cyclopentyl acetate 
• 53226-42-9 N-cyclopentylbenzamide 
• 16868-13-6 acrylic acid cyclopentyl ester 
• 4596-40-1 cyclopentylcarbinyl p-bromobenzenesulfonate 

Relevant articles and documents

Thermodynamic properties, conformational composition, and phase transitions of cyclopentanol

Thermodynamic properties of cyclopentanol were studied.The molar heat capacity of c-C5H9OH(cr and l) in the temperature range T = 5.4 K to 303.0 K was measured by vacuum adiabatic calorimetry.Three solid-to-solid transitions were found: at T = 176 K with ΔtrsHm = (57 +/- 5) J*mol-1; at T = 202.6 K with ΔtrsHm = (3366 +/- 14) J*mol-1, and at T = 234 K with ΔtrsHm = (55 +/- 6) J*mol-1.The fusion temperature of c-C5H9OH is 255.6 K, and ΔfusHm = (1227 +/- 5) J*mol-1.Basic thermodynamic functions at T = 298.15 K in the liquid state are Cs,m = (182.48 +/- 0.73) J*K-1*mol-1, Sm = (204.14 +/- 0.90) J*K-1*mol-1, and Φm = (96.98 +/- 0.40) J*K-1*mol-1.The enthalpy of vaporization was measured with a heat-conducting microcalorimeter: ΔvapHm(298.15 K) = (57.05 +/- 0.65) kJ*mol-1.Using these and literature data, the standard molar entropy of c-C5H9OH(g) was determined: S0m(g, 340 K) = (362.9 +/- 2.4) J*K-1*mol-1.Conformational analysis was made by the molecular-mechanics method, and statistical calculations of standard molar thermodynamic functions in the ideal-gas state were carried out on the basis of molecular parameters and conformational properties.The calculated entropy value at T = 340 K was put into agreement with the experimental one by adjusting the pseudorotational moment of inertia.The standard molar entropy and molar heat capacity of c-C5H9OH in the ideal-gas state at T = 298.15 K are 347.91 J*K-1*mol-1 and 105.43 J*K-1*mol-1, respectively.Thermodynamic analysis of phase transitions in the condensed state was made.It was shown that pseudorotation in the plastic crystal state of c-C5H9OH is significantly hindered.Thermodynamic quantities allowed us to propose the absence of a non-equilibrium mixture of conformers at T -> 0.An anomalously low entropy difference between liquid and rigid crystal of cyclopentanol in comparison with other cyclopentane derivatives shows a relatively high ordering in the liquid.

An efficient method for the catalytic aerobic oxidation of cycloalkanes using 3,4,5,6-Tetrafluoro-N-Hydroxyphthalimide (F4-NHPI)

N-Hydroxyphthalimide (NHPI) is known to be an effective catalyst for the oxidation of hydrocarbons. The catalytic activity of NHPI derivatives is generally increased by introducing an electron-withdrawing group on the benzene ring. In a previous report, two NHPI derivatives containing fluorinated alkyl chain were prepared and their catalytic activity was investigated in the oxidation of cycloalkanes. It was found that the fluorinated NHPI derivatives showed better yields for the oxidation reaction. As a continuation of our work with fluorinated NHPI derivatives, our next aim was to investigate the catalytic activity of the NHPI derivatives by introducing fluorine atoms in the benzene ring of NHPI. In the present research, 3,4,5,6-Tetrafluoro-N-Hydroxyphthalimide (F4-NHPI) is prepared and its catalytic activity has been investigated in the oxidation of two different cycloalkanes for the first time. It has been found that F4-NHPI showed higher catalytic efficiency compared with that of the parent NHPI catalyst in the present reactions. The presence of a fluorinated solvent and an additive was also found to accelerate the oxidation.

Biomimetic ketone reduction by disulfide radical anion

The conversion of ribonucleosides to 2′-deoxyribonucleosides is catalyzed by ribonucleoside reductase enzymes in nature. One of the key steps in this complex radical mechanism is the reduction of the 3′-ketodeoxynucleotide by a pair of cysteine residues, providing the electrons via a disulfide radical anion (RSSR??) in the active site of the enzyme. In the present study, the bioinspired conversion of ketones to corresponding alcohols was achieved by the intermediacy of disulfide radical anion of cysteine (CysSSCys)?? in water. High concentration of cysteine and pH 10.6 are necessary for high-yielding reactions. The photoinitiated radical chain reaction includes the one-electron reduction of carbonyl moiety by disulfide radical anion, protonation of the resulting ketyl radical anion by water, and H-atom abstraction from CysSH. The (CysSSCys)?? transient species generated by ionizing radiation in aqueous solutions allowed the measurement of kinetic data with ketones by pulse radiolysis. By measuring the rate of the decay of (CysSSCys)?? at λmax = 420 nm at various concentrations of ketones, we found the rate constants of three cyclic ketones to be in the range of 104–105 M?1s?1 at ~22?C.

Hydrogen-Catalyzed Acid Transformation for the Hydration of Alkenes and Epoxy Alkanes over Co-N Frustrated Lewis Pair Surfaces

Hydrogen (H2) is widely used as a reductant for many hydrogenation reactions; however, it has not been recognized as a catalyst for the acid transformation of active sites on solid surface. Here, we report the H2-promoted hydration of alkenes (such as styrenes and cyclic alkenes) and epoxy alkanes over single-atom Co-dispersed nitrogen-doped carbon (Co-NC) via a transformation mechanism of acid-base sites. Specifically, the specific catalytic activity and selectivity of Co-NC are superior to those of classical solid acids (acidic zeolites and resins) per micromole of acid, whereas the hydration catalysis does not take place under a nitrogen atmosphere. Detailed investigations indicate that H2 can be heterolyzed on the Co-N bond to form Hδ-Co-N-Hδ+ and then be converted into OHδ-Co-N-Hδ+ accompanied by H2 generation via a H2O-mediated path, which significantly reduces the activation energy for hydration reactions. This work not only provides a novel catalytic method for hydration reactions but also removes the conceptual barriers between hydrogenation and acid catalysis.