614-32-4

Basic information

• Product Name: m-tolyl benzoate
• Synonyms: m-tolyl benzoate;3-Methylphenyl benzoate;Benzenecarboxylic acid 3-methylphenyl ester;Benzoic acid m-methylphenyl ester;Benzoic acid m-tolyl ester;benzoic acid (3-methylphenyl) ester;meta-cresyl benzoate
• CAS NO: 614-32-4
• Molecular Formula: C₁₄H₁₂O₂
• Molecular Weight: 212.24388
• EINECS: 210-378-0
• Mol File: 614-32-4.mol

Chemical Properties

• Boiling Point: 314.6°C at 760 mmHg
• Flash Point: 129.1°C
• Appearance: /
• Density: 1.122g/cm³
• Vapor Pressure: 0.000462mmHg at 25°C
• Refractive Index: 1.577
• CAS DataBase Reference: m-tolyl benzoate(CAS DataBase Reference)
• NIST Chemistry Reference: m-tolyl benzoate(614-32-4)
• EPA Substance Registry System: m-tolyl benzoate(614-32-4)

Safety Data

• Hazardous Substances Data: 614-32-4(Hazardous Substances Data)

Usage

Uses

Used in Flavor and Fragrance Industry:
m-Tolyl benzoate is used as a flavoring agent and fragrance in the food and cosmetic industries due to its pleasant and fruity scent.
Used in Insect Repellent Products:
m-Tolyl benzoate is used as an active ingredient in insect repellents because of its insecticidal properties, providing protection against various insects.
Used in Antimicrobial Products:
m-Tolyl benzoate is used in antimicrobial products due to its antimicrobial properties, helping to prevent the growth of bacteria and other microorganisms.
Used in Pharmaceutical Production:
m-Tolyl benzoate is used in the production of pharmaceuticals, contributing to the development of various medications.
Used as a Solvent in Organic Synthesis:
m-Tolyl benzoate is used as a solvent in organic synthesis, aiding in the chemical reactions and processes involved in creating different organic compounds.
It is important to handle m-tolyl benzoate with care, as it can be harmful if ingested or inhaled, and can cause skin and eye irritation upon contact.

InChI:InChI=1/C14H12O2/c1-11-6-5-9-13(10-11)16-14(15)12-7-3-2-4-8-12/h2-10H,1H3

Upstream product

• 98-88-4 benzoyl chloride 
• 108-39-4 3-methyl-phenol 
• 65-85-0 benzoic acid 
• 16136-81-5 Benzoyl-isopropyloxycarbonyl-peroxid 
• 108-88-3 toluene 
• 94-36-0 dibenzoyl peroxide 
• 4072-08-6 (2-hydroxy-3-methylphenyl)(phenyl)methanone 
• 3098-18-8 2-hydroxy-4-methylbenzophenone 
• 10425-07-7 4-hydroxy-2-methylbenzophenone 
• 50597-28-9 (2-Hydroxy-6-methylphenyl)phenylketon 
• 614-45-9 tert-Butyl peroxybenzoate 
• 7446-70-0 aluminium trichloride 
• 98-07-7 Benzotrichlorid 
• 93-59-4 Perbenzoic acid 

Downstream Products

• 3098-18-8 2-hydroxy-4-methylbenzophenone 
• 10425-07-7 4-hydroxy-2-methylbenzophenone 
• 84196-13-4 4-chloro-3-methylphenyl benzoate 
• 137937-47-4 (2-hydroxy-4-methylphenyl)(phenyl)methanone benzoate 
• 138372-90-4 α-(3-methylphenoxy)styrene 
• 129250-89-1 α-bromo-3-methylphenyl benzoate 
• 108-39-4 3-methyl-phenol 
• 50597-28-9 (2-Hydroxy-6-methylphenyl)phenylketon 
• 93-89-0 benzoic acid ethyl ester 
• 20227-79-6 3-methylphenolate anion 
• 137956-29-7 4-hydroxy-2-methylbenzophenone benzoate 
• 65-85-0 benzoic acid 
• 179019-05-7 [2-methyl-4-(2-pyrrolidin-1-yl-ethoxy)-phenyl]-phenyl-methanol 
• 179018-61-2 [2-methyl-4-(2-pyrrolidin-1-yl-ethoxy)-phenyl]-phenyl-methanone 

Relevant articles and documents

Hydrogen-bond-assisted transition-metal-free catalytic transformation of amides to esters

The amide C-N cleavage has drawn a broad interest in synthetic chemistry, biological process and pharmaceutical industry. Transition-metal, luxury ligand or excess base were always vital to the transformation. Here, we developed a transition-metal-free hydrogen-bond-assisted esterification of amides with only catalytic amount of base. The proposed crucial role of hydrogen bonding for assisting esterification was supported by control experiments, density functional theory (DFT) calculations and kinetic studies. Besides broad substrate scopes and excellent functional groups tolerance, this base-catalyzed protocol complements the conventional transition-metal-catalyzed esterification of amides and provides a new pathway to catalytic cleavage of amide C-N bonds for organic synthesis and pharmaceutical industry. [Figure not available: see fulltext.]

Supramolecular Pd(II) complex of DPPF and dithiolate: An efficient catalyst for amino and phenoxycarbonylation using Co2(CO)8 as sustainable C1 source

Highly active, efficient and robust “dppf ligated tetranuclear palladium dithiolate complex” was synthesized and applied as a catalyst for chemical fixation of carbon monoxide for the synthesis value added chemicals such as tertiary amide and aromatic esters. The synthesized catalyst was characterized using different analytical techniques such as elemental analysis, 1H and 31P NMR spectroscopy. The use of Co2(CO)8 as a cheap, less toxic and low melting solid surrogate are additional advantages over the current protocol. The catalyst showed superior activity towards the Amino (10?3 mol % catalyst) and Phenoxycarbonylation (10-2 mol % catalyst) and high TON (104 to 103) and TOF (103 to 102 h-1). The Betol and Lintrin (active drug molecules) were synthesized under an optimized reaction condition. The scalability of the current protocol has been demonstrated up-to the gram level.

Oxime palladacycle in PEG as a highly efficient and recyclable catalytic system for phenoxycarbonylation of aryl iodides with phenols

In this report, we have developed a sustainable protocol for the synthesis of aromatic esters by a carbonylative method using di-μ-chlorobis [5-hydroxy-2-[1-(hydroxyimino-?N) ethyl] phenyl-?C] palladium (II) dimer (1) catalyst in PEG-400 as a greener and recyclable solvent. The reaction is carried out at room temperature using CO in a balloon. Good to excellent yield of various esters can be synthesize using this protocol. Direct insertion of CO moiety leads to the high atom and step economy. Compared to previous protocol this phosphine free approach for the synthesis of aromatic esters provides high Turnover Number (TON) and Turnover Frequency (TOF). Developed approach has an alternative route for use of conventional palladium precursor with high conversion and selectivity. The catalyst system and product can easily be separated using diethyl ether as a solvent. The Pd/PEG-400 system could be reused up to a fifth consecutive cycle without any loss of its activity and selectivity.

Palladium-Catalyzed Aerobic Oxidative Coupling of Amides with Arylboronic Acids by Cooperative Catalysis

The first fluoride and palladium co-catalyzed conversion of amide to ester through an aerobic oxidative coupling pathway is reported. This new approach presents a practical process that employs easily available oxygen and commercially available arylboronic acids as coupling partners, uses a wide range of N- tosylamides, and proceeds under mild reaction conditions. This protocol demonstrates broad functional group tolerance, and provides an alternative option to synthesize esters from N-tosylamides which obtained by simply N-functionalization of secondary amides.

Base-Promoted Amidation and Esterification of Imidazolium Salts via Acyl C-C bond Cleavage: Access to Aromatic Amides and Esters

Imidazolium salts have been effectively employed as suitable acyl transfer agents in amidation and esterification in organic synthesis. The weak acyl C(O)-C imidazolium bond was exploited to generate acyl electrophiles, which further react with amines and alcohols to afford amides and esters. The broad substrate scope of anilines and benzylic amines and base-promoted conditions are the benefits of this route. Interestingly, phenol, benzylic alcohols, and a biologically active alcohol can also be subjected to esterification under the optimized conditions.

Electrodimerization of N-Alkoxyamides for Zinc(II) Catalyzed Phenolic Ester Synthesis under Mild Reaction Conditions

An electrochemical On-Off method for phenolic ester synthesis from N-alkoxyamides has been reported. This one-pot protocol begins with rapid and selective electrodimerization of the amide using n-Bu4NI (TBAI) as an electrocatalyst. The reaction proceeds further in the absence of current via Zn catalyzed C?N bond activation of the amide dimer followed by its coupling with phenol to form the ester. The present methodology is ligand-free and takes place under mild reaction conditions. This transformation incorporates a wide variety of phenols and amide substrates leading to the formation of functionalized esters highlighting its versatility. (Figure presented.).

Highly Active Manganese-Mediated Acylation of Alcohols with Acid Chlorides or Anhydrides

To explore further the practical uses of highly active manganese (Mn?), a variety of alcohols were treated with Mn?, and the resulting complexes were coupled with acid chlorides and/or acetic anhydride in the absence of any extra catalyst. The subsequent reactions took place smoothly under mild conditions, providing the corresponding O-acylation products in good to excellent isolated yields.

Series of high spin mononuclear iron(III) complexes with Schiff base ligands derived from 2-hydroxybenzophenones

The reaction of various phenols with benzoyl chloride afforded the derivatives of phenyl benzoate that subsequently underwent Fries rearrangement. The obtained 2-hydroxybenzophenone analogues were combined with linear aliphatic triamines, which afforded pentadentate Schiff base ligands. Moreover, nine new iron(iii) complexes with the general formula [Fe(Ln)X] (where, Ln is the dianion of the pentadentate Schiff base ligand, N,N′-bis((2-hydroxy-5-methylphenyl)phenyl)methylidene-1,5-diamino-3-azapentane = H2L1, N,N′-bis((2-hydroxy-3,5-dimethylphenyl)phenyl)methylidene-1,5-diamino-3-azapentane = H2L2, N,N′-bis((2-hydroxy-5-chlorophenyl)phenyl)methylidene-1,5-diamino-3-azapentane = H2L3, N,N′-bis((2-hydroxy-4-methylphenyl)phenyl)methylidene-1,5-diamino-3-azapentane = H2L4, N,N′-bis((2-hydroxy-5-bromophenyl)phenyl)methylidene-1,7-diamino-4-azaheptane = H2L5, N,N′-bis((2-hydroxy-5-bromophenyl)phenyl)methylidene-1,7-diamino-4-methyl-4-azaheptane = H2L6 and X is the chlorido, azido or isocyanato terminal ligand) were synthesized and characterized via elemental analysis, and IR and UV-VIS spectroscopy; in addition, the crystal structures of all the complexes were determined by X-ray diffraction. Magnetic investigation reveals high spin state behaviour in all the reported compounds. DFT calculations and analysis of the magnetic functions allowed to extract absolute values of the zero field splitting parameters and exchange coupling constants.

Palladium Catalyzed Carbonylative Coupling for Synthesis of Arylketones and Arylesters Using Chloroform as the Carbon Monoxide Source

We describe a modular, palladium catalyzed synthesis of aryl(hetero)aryl benzophenones and aryl benzoates from aryl(hetero)aryl halides using CHCl3 as the carbonyl source in the presence of KOH. The reaction occurs in tandem through an initial carbonylation to generate an aroyl halide, which undergoes coupling with arylboronic acids, bornonates, and phenols. Direct carbonylative coupling of indoles at the third position has also been accomplished under slightly modified reaction conditions by in situ activation of the C-H bond. Notably, CHCl3 is a convenient and safe alternation of CO gas, provides milder reaction conditions with high functional group tolerance, and gives the products in moderate to good yields.

Palladium-Catalyzed Oxidative Carbonylation of Aryl Hydrazines with CO and O2 at Atmospheric Pressure

Palladium-catalyzed aerobic oxidative aminocarbonylation and alkoxycarbonylation reactions with aryl hydrazines as coupling partners have been developed. The oxidative carbonylation of aryl hydrazines proceeded smoothly at atmospheric pressure CO, employi