699-02-5

Basic information

• Product Name: 2-(4-METHYLPHENYL)ETHANOL
• Synonyms: 2-(4-METHYLPHENYL)ETHANOL;2-(P-TOLYL)ETHANOL;4-METHYLPHENETHYL ALCOHOL;P-METHYLPHENETHYL ALCOHOL;2-(p-Methylphenyl)ethanol;4-methyl-benzeneethano;4-Methylbenzeneethanol;4-methyl-Benzeneethanol
• CAS NO: 699-02-5
• Molecular Formula: C₉H₁₂O
• Molecular Weight: 136.19
• EINECS: 211-824-7
• Product Categories: Alcohols;C9 to C30;Oxygen Compounds;Building Blocks;C9 to C10;Chemical Synthesis;Organic Building Blocks;Oxygen Compounds
• Mol File: 699-02-5.mol

Chemical Properties

• Boiling Point: 244-245 °C(lit.)
• Flash Point: 225 °F
• Appearance: Clear colorless to faintly yellow liquid
• Density: 0.978 g/mL at 25 °C(lit.)
• Refractive Index: n20/D 1.526(lit.)
• Storage Temp.: Sealed in dry,Room Temperature
• PKA: 14.92±0.10(Predicted)
• CAS DataBase Reference: 2-(4-METHYLPHENYL)ETHANOL(CAS DataBase Reference)
• NIST Chemistry Reference: 2-(4-METHYLPHENYL)ETHANOL(699-02-5)
• EPA Substance Registry System: 2-(4-METHYLPHENYL)ETHANOL(699-02-5)

Safety Data

• Safety Statements: 24/25
• WGK Germany: 3
• TSCA: Yes
• Hazardous Substances Data: 699-02-5(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical and Chemical Research:
2-(4-METHYLPHENYL)ETHANOL is used as a reagent for the determination of adducts of 1,2and 1,4-benzoquinone with cysteine residues of hemoglobin and albumin. This application is particularly important in the study of the effects of quinones on proteins and their potential implications in various diseases.
Used in the Flavor and Fragrance Industry:
2-(4-METHYLPHENYL)ETHANOL is used as a flavoring agent for its distinctive aromatic properties. It contributes to the creation of various scents and flavors in the production of perfumes, cosmetics, and the food and beverage industry.
Used in the Chemical Synthesis Industry:
2-(4-METHYLPHENYL)ETHANOL serves as a key intermediate in the synthesis of various chemicals and pharmaceuticals. Its unique structure allows it to be a valuable building block in the development of new compounds with potential applications in different fields.

InChI:InChI=1/C9H12O/c1-8-2-4-9(5-3-8)6-7-10/h2-5,10H,6-7H2,1H3

Upstream product

• 75-21-8 oxirane 
• 6749-78-6 4-methylphenylmagnesium iodide 
• 108-88-3 toluene 
• 4294-57-9 para-methylphenylmagnesium bromide 
• 13107-39-6 2-(4-methylphenyl)oxirane 
• 589-18-4 4-Methylbenzyl alcohol 
• 22532-47-4 4-methylphenethyl acetate 
• 589-29-7 p-xylylene glycol 
• 622-47-9 4-tolylacetic acid 
• 14062-19-2 p-tolylacetic acid ethyl ester 
• 104-09-6 4-methylphenylacetaldehyde 
• 3261-62-9 2-(p-tolyl)ethylamine 
• 107-07-3 2-chloro-ethanol 
• 106-38-7 para-bromotoluene 

Downstream Products

• 99187-87-8 chloromethyl-(4-methyl-phenethyl)-ether 
• 103261-92-3 3,4-dihydro-7-methyl-1H-isochromene 
• 622-97-9 1-ethenyl-4-methylbenzene 
• 6529-51-7 2-(4-methylphenyl)ethyl bromide 
• 32327-68-7 p-methyl-2-phenylethyl chloride 
• 854258-80-3 bis-(4-methyl-phenethyl)-ether 
• 22545-18-2 3,5-dinitro-benzoic acid-(4-methyl-phenethyl ester) 
• 32504-14-6 (4-methyl-phenethyl)-hydrazine 
• 66865-86-9 1-(2-methanesulfonyloxyethyl)-4-methylbenzene 
• 72567-42-1 4-[2-(4-methylphenyl)ethoxy]nitrobenzene 
• 14503-40-3 2-(4-methylphenyl)ethyl tosylate 
• 104-09-6 4-methylphenylacetaldehyde 
• 120391-67-5 1-iodo-2-(4-methylphenyl)ethane 
• 7530-13-4 N-[2-(4-methylphenyl)ethyl]piperidine 

Relevant articles and documents

Borane evolution and its application to organic synthesis using the phase-vanishing method

Although borane is a useful reagent, it is difficult to handle. In this study, borane was generated in situ from NaBH4 or nBu4NBH4 with several oxidants using a phase-vanishing (PV) method. The borane generated was directly reacted with alkenes, affording the desired alcohols in good yields after oxidation with H2O2 under basic conditions. The selective reduction of carboxylic acids with the evolved borane was examined. The organoboranes generated by the PV method successfully underwent Suzuki–Miyaura coupling. Using this PV system, reactions with borane can be carried out easily and safely in a common test tube.

Tropylium-Promoted Hydroboration Reactions: Mechanistic Insights Via Experimental and Computational Studies

Hydroboration reaction of alkynes is one of the most synthetically powerful tools to access organoboron compounds, versatile precursors for cross-coupling chemistry. This type of reaction has traditionally been mediated by transition-metal or main group catalysts. Herein, we report a novel method using tropylium salts, typically known as organic oxidants and Lewis acids, to promote the hydroboration reaction of alkynes. A broad range of vinylboranes can be easily accessed via this metal-free protocol. Similar hydroboration reactions of alkenes and epoxides can also be efficiently catalyzed by the same tropylium catalysts. Experimental studies and DFT calculations suggested that the reaction follows an uncommon mechanistic pathway, which is triggered by the hydride abstraction of pinacolborane with tropylium ion. This is followed by a series ofin situcounterion-activated substituent exchanges to generate boron intermediates that promote the hydroboration reaction.

Regiodivergent Hydroborative Ring Opening of Epoxides via Selective C-O Bond Activation

A magnesium-catalyzed regiodivergent C-O bond cleavage protocol is presented. Readily available magnesium catalysts achieve the selective hydroboration of a wide range of epoxides and oxetanes yielding secondary and tertiary alcohols in excellent yields and regioselectivities. Experimental mechanistic investigations and DFT calculations provide insight into the unexpected regiodivergence and explain the different mechanisms of the C-O bond activation and product formation.

Diaminodiphosphine tetradentate ligand and ruthenium complex thereof, and preparation methods and applications of ligand and complex

The invention discloses a diaminodiphosphine tetradentate ligand and a ruthenium complex thereof, and preparation methods and applications of the ligand and the complex, and provides a ruthenium complex represented by a formula I, wherein L is a diaminodiphosphine tetradentate ligand represented by a formula II, and X and Y are respectively and independently chlorine ion, bromine ion, iodine ion,hydrogen negative ion or BH4. According to the present invention, the ruthenium complex exhibits excellent catalytic activity in the catalytic hydrogenation reactions of ester compounds, has high yield and high chemical selectivity, is compatible with conjugated and non-conjugated carbon-carbon double bond, carbon-carbon triple bond, epoxy, halogen, carbonyl and other functional groups, and hasgreat application prospects.

Ruthenium-Catalyzed Selective Hydrogenation of Epoxides to Secondary Alcohols

A ruthenium(II)-catalyzed highly selective Markovnikov hydrogenation of terminal epoxides to secondary alcohols is reported. Diverse substitutions on the aryl ring of styrene oxides are tolerated. Benzylic, glycidyl, and aliphatic epoxides as well as diepoxides also underwent facile hydrogenation to provide secondary alcohols with exclusive selectivity. Metal-ligand cooperation-mediated ruthenium trans-dihydride formation and its reaction involving oxygen and the less substituted terminal carbon of the epoxide is envisaged for the origin of the observed selectivity.

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.

Regioselective hydrosilylation of epoxides catalysed by nickel(II) hydrido complexes

Bench-stable nickel fluoride complexes bearing NNN pincer ligands have been employed as precursors for the regioselective hydrosilylation of epoxides at room temperature. A nickel hydride assisted epoxide opening is followed by the cleavage of the newly formed nickel oxygen bond by σ-bond metathesis with a silane.

Biocatalytic Formal Anti-Markovnikov Hydroamination and Hydration of Aryl Alkenes

Biocatalytic anti-Markovnikov alkene hydroamination and hydration were achieved based on two concepts involving enzyme cascades: epoxidation-isomerization-amination for hydroamination and epoxidation-isomerization-reduction for hydration. An Escherichia coli strain coexpressing styrene monooxygenase (SMO), styrene oxide isomerase (SOI), ω-transaminase (CvTA), and alanine dehydrogenase (AlaDH) catalyzed the hydroamination of 12 aryl alkenes to give the corresponding valuable terminal amines in high conversion (many ≥86%) and exclusive anti-Markovnikov selectivity (>99:1). Another E. coli strain coexpressing SMO, SOI, and phenylacetaldehyde reductase (PAR) catalyzed the hydration of 12 aryl alkenes to the corresponding useful terminal alcohols in high conversion (many ≥80%) and very high anti-Markovnikov selectivity (>99:1). Importantly, SOI was discovered for stereoselective isomerization of a chiral epoxide to a chiral aldehyde, providing some insights on enzymatic epoxide rearrangement. Harnessing this stereoselective rearrangement, highly enantioselective anti-Markovnikov hydroamination and hydration were demonstrated to convert α-methylstyrene to the corresponding (S)-amine and (S)-alcohol in 84-81% conversion with 97-92% ee, respectively. The biocatalytic anti-Markovnikov hydroamination and hydration of alkenes, utilizing cheap and nontoxic chemicals (O2, NH3, and glucose) and cells, provide an environmentally friendly, highly selective, and high-yielding synthesis of terminal amines and alcohols.

Anti-Markovnikov alkene oxidation by metal-oxo–mediated enzyme catalysis

Catalytic anti-Markovnikov oxidation of alkene feedstocks could simplify synthetic routes to many important molecules and solve a long-standing challenge in chemistry. Here we report the engineering of a cytochrome P450 enzyme by directed evolution to catalyze metal-oxo–mediated anti-Markovnikov oxidation of styrenes with high efficiency. The enzyme uses dioxygen as the terminal oxidant and achieves selectivity for anti-Markovnikov oxidation over the kinetically favored alkene epoxidation by trapping high-energy intermediates and catalyzing an oxo transfer, including an enantioselective 1,2-hydride migration. The anti-Markovnikov oxygenase can be combined with other catalysts in synthetic metabolic pathways to access a variety of challenging anti-Markovnikov functionalization reactions.

Antiproliferative activity and SARs of caffeic acid esters with mono-substituted phenylethanols moiety

A series of CAPE derivatives with mono-substituted phenylethanols moiety were synthesized and evaluated by MTT assay on growth of 4 human cancer cell lines (Hela, DU-145, MCF-7 and ECA-109). The substituent effects on the antiproliferative activity were systematically investigated for the first time. It was found that electron-donating and hydrophobic substituents at 2′-position of phenylethanol moiety could significantly enhance CAPE's antiproliferative activity. 2′-Propoxyl derivative, as a novel caffeic acid ester, exhibited exquisite potency (IC50?=?0.4?±?0.02 & 0.6?±?0.03?μM against Hela and DU-145 respectively).