4423-09-0

Basic information

• Product Name: 3-(4-METHYLPHENYL)PYRIDINE
• Synonyms: 3-(4-METHYLPHENYL)PYRIDINE;AKOS BAR-0410;3-(p-Tolyl)pyridine;3-p-Tolylpyridine;3-(p-Methylphenyl)pyridine;4-(3-Pyridyl)toluene;5-(4-Methylphenyl)pyridine;4-(3-Pyridinyl)toluene
• CAS NO: 4423-09-0
• Molecular Formula: C₁₂H₁₁N
• Molecular Weight: 169.22
• Mol File: 4423-09-0.mol

Chemical Properties

• Melting Point: 38-39 °C
• Boiling Point: 293.9±9.0 °C(Predicted)
• Appearance: /
• Density: 1.030±0.06 g/cm3(Predicted)
• PKA: 5.08±0.10(Predicted)
• CAS DataBase Reference: 3-(4-METHYLPHENYL)PYRIDINE(CAS DataBase Reference)
• NIST Chemistry Reference: 3-(4-METHYLPHENYL)PYRIDINE(4423-09-0)
• EPA Substance Registry System: 3-(4-METHYLPHENYL)PYRIDINE(4423-09-0)

Safety Data

• Hazardous Substances Data: 4423-09-0(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Industry:
3-(4-METHYLPHENYL)PYRIDINE is used as a building block for the synthesis of various pharmaceuticals, contributing to the development of new drugs and therapeutic agents. Its unique chemical structure allows for the creation of diverse medicinal compounds with potential applications in treating a wide range of diseases and conditions.
Used in Agrochemical Industry:
3-(4-METHYLPHENYL)PYRIDINE is utilized as a key component in the synthesis of agrochemicals, such as pesticides and herbicides. Its incorporation into these products helps enhance their effectiveness in controlling pests and weeds, thereby improving crop yields and ensuring food security.
Used in Coordination Chemistry:
3-(4-METHYLPHENYL)PYRIDINE is employed as a ligand in coordination chemistry, playing a crucial role in the formation of metal complexes. These complexes exhibit unique properties and applications in various fields, including catalysis, materials science, and supramolecular chemistry.
Used in Organic Synthesis:
3-(4-METHYLPHENYL)PYRIDINE is used as a reagent in organic synthesis, facilitating the formation of a variety of organic compounds. Its presence in reactions can enhance the yield and selectivity of desired products, making it a valuable tool in the synthesis of complex organic molecules.

Upstream product

• 110-86-1 pyridine 
• 51274-57-8 1-(4-Methylphenyl)-3,3-(1,5-pentanediyl)triazene 
• 599-66-6 bis(4-methylphenyl) sulfone 
• 459-44-9 4-methylbenzenediazonium tetrafluoroborate 
• 1120-90-7 3-iodopyridine 
• 108-88-3 toluene 
• 106-38-7 para-bromotoluene 
• 89878-14-8 3-Diethylboranylpyridine 
• 626-55-1 3-Bromopyridine 
• 5720-05-8 4-methylphenylboronic acid 
• 626-60-8 3-Chloropyridine 
• 18412-57-2 p-tolyltriethoxysilane 
• 104-92-7 1-bromo-4-methoxy-benzene 
• 17873-01-7 (4-methylphenyl)trimethoxysilane 

Downstream Products

• 200282-69-5 3-(4-methylphenyl)pyridine N-oxide 
• 179057-21-7 3-(4-Bromomethyl-phenyl)-pyridine 
• 143425-48-3 3-(4-methylphenyl)pyridine-2-carbonitrile 
• 200282-70-8 2-acetyl-3-(4-methylphenyl)pyridine 
• 755699-91-3 3-(4-methylphenyl)piperidine 

Relevant articles and documents

Isotope Effects in the p-Tolylation of Pyridine

p-Toluoyl peroxide, p-iodotuluene, and di-p-tolyl sulfone, sulfoxide, and sulfide were photolyzed in an equimolar pyridine-pyridine-d5 mixture to give rise to isomeric p-tolylpyridines (α, β, and γ) and their deuterated compounds.Isotopic distribution ratios (YH/YD) in the isomeric products were determined to be slightly larger than unity.

Organocatalytic synthesis of (Het)biaryl scaffoldsviaphotoinduced intra/intermolecular C(sp2)-H arylation by 2-pyridone derivatives

A uniqueN,O-bidentate ligand 6-oxo-1,6-dihydro-pyridone-2-carboxylic acid dimethylamide (L1) catalyzed direct C(sp2)-H (intra/intermolecular) arylation of unactivated arenes has been developed to expedite access to (Het)biaryl scaffolds under UV-irradiation at room temperature. The protocol tolerated diverse functional groups and substitution patterns, affording the target products in moderate to excellent yields. Mechanistic investigations were also carried out to better understand the reaction pathway. Furthermore, the synthetic applicability of this unified approach has been showcasedviathe construction of biologically relevant 4-quinolone, tricyclic lactam and sultam derivatives.

Decarbonylative Pd-Catalyzed Suzuki Cross-Coupling for the Synthesis of Structurally Diverse Heterobiaryls

Heteroaromatic biaryls are core scaffolds found in a plethora of pharmaceuticals; however, their direct synthesis by the Suzuki cross-coupling is limited to heteroaromatic halide starting materials. Here, we report a direct synthesis of diverse nitrogen-containing heteroaromatic biaryls by Pd-catalyzed decarbonylative Suzuki cross-coupling of widely available heterocyclic carboxylic acids with arylboronic acids. The practical and modular nature of this cross-coupling enabled the straightforward preparation of >45 heterobiaryl products using pyridines, pyrimidines, pyrazines, and quinolines in excellent yields. We anticipate that the modular nature of this protocol will find broad application in medicinal chemistry and drug discovery research.

Suzuki-Miyaura Cross-Coupling Reaction with Potassium Aryltrifluoroborate in Pure Water Using Recyclable Nanoparticle Catalyst

This paper describes the Suzuki Miyaura cross-coupling reaction of aryl bromides with potassium aryltrifluoroborates in water catalyzed by linear polystyrene-stabilized PdO nanoparticles (PSPdONPs). The reaction of aryl bromides having electron-withdrawing groups or electron-donating groups took place smoothly to give the corresponding coupling product in high yields. The catalyst recycles five times without significant loss of catalytic activity although a little bit increase in size of PdNPs was observed after the reaction.

New Nickel-Based Catalytic System with Pincer Pyrrole-Functionalized N-Heterocyclic Carbene as Ligand for Suzuki-Miyaura Cross-Coupling Reactions

A new catalytic system with Ni(NO3)2·6H2O as the catalyst and a pincer pyrrole-functionalized N-heterocyclic carbene as the ligand was employed in the Suzuki-Miyaura cross-coupling reactions of aryl iodides with arylboronic acids. With 5 mol% catalyst, the catalytic reactions proceeded at 160 °C, giving coupling products in isolated yields of up to 94% in short reaction times (1-4 h). The system worked efficiently with aryl iodides bearing electron-donating or electron-withdrawing groups and arylboronic acids with electron-donating groups. Steric effects were observed for both aryl iodides and arylboronic acids. It is proposed that the reactions underwent a Ni(I)/Ni(III) catalytic cycle.

4-Amino-1,2,4-triazoles-3-thiones and 1,3,4-oxadiazoles-2-thiones·palladium(II) recoverable complexes as catalysts in the sustainable Suzuki-Miyaura cross-coupling reaction

The Suzuki-Miyaura cross-coupling reaction using 4-amino-1,2,4-triazoles and 1,3,4-oxadiazoles-2-thiones·palladium (II) is studied. The reaction is optimized and the most appropriate catalytic complex is tested with several aryl halides, boronic acids in an environmentally benign solvent system (H2O/EtOH). The recovery of the catalytic species is also surveyed because of the nature of the employed solvent. A domino process is efficiently carried out following the standard conditions. Several surface parameters of the ligands are analyzed and the resulting values are extrapolated to the insoluble palladium catalyst.

para-Selective arylation and alkenylation of monosubstituted arenes using thianthreneS-oxide as a transient mediator

Using thianthreneS-oxide (TTSO) as a transient mediator,para-arylation and alkenylation of mono-substituted arenes have been demonstratedviaapara-selective thianthrenation/Pd-catalyzed thio-Suzuki-Miyaura coupling sequence under mild conditions. This reaction features a broad substrate scope, and functional group and heterocycle tolerance. The versatility of this approach was further demonstrated by late-stage functionalization of complex bioactive scaffolds, and direct synthesis of some pharmaceuticals, including Tetriprofen, Ibuprofen, Bifonazole, and LJ570.

Preparation method of para-substituted aryl compound

The invention discloses a preparation method of a para-substituted aryl compound shown as a formula (I) which is described in the specfication. The preparation method is characterized by comprising the following step of: subjecting an aryl sulfonium salt shown as a formula (II) which is described in the specfication and boride to a coupling reaction in a solvent in an inert atmosphere under the action of alkali and a palladium catalyst to obtain the para-substituted aryl compound. According to the method, mono-substituted aromatic hydrocarbon is taken as a substrate, the aryl sulfonium salt isconstructed in situ, and the palladium catalyst catalyzes the aryl sulfonium salt constructed in situ to undergo the Suzuki-Miyaura coupling reaction, so a mono-substituted aromatic hydrocarbon para-arylation or alkenylation product is constructed quickly and efficiently. The method is mild in conditions, high in substrate universality and wide in tolerance of a heterocyclic coupling substrate.

Unified Protocol for Fe-Based Catalyzed Biaryl Cross-Couplings between Various Aryl Electrophiles and Aryl Grignard Reagents

The combination of commonly used FeCl3/SIPr with Ti(OEt)4/PhOM enabled a highly general iron-based catalyst system, which could efficiently catalyze the biaryl coupling reaction between various electrophiles (I, Br, Cl, OTs, OCONMe2, OSO2NMe2) and common or functionalized aryl Grignard reagents with high functional group tolerance. Selective couplings of aryl iodides and bromides over the corresponding oxygen-based electrophiles have been achieved, and thus a terphenyl acid intermediate for anidulafungin was conveniently synthesized via an orthogonal coupling strategy.

Schiff-based Pd(II)/Fe(III) bimetallic self-assembly monolayer—preparation, structure, catalytic dynamic and synergistic

Graphene oxide supported Pd (II)/Fe (III) bimetallic catalytic monolayer (denoted as GO@H-Pd/Fe) was prepared and characterized. Its catalytic performances for Suzuki coupling reaction, synergetic effect and catalytic mechanism were systematic investigated. Results showed that orientation, composition and distribution of catalyst had efficient effect on catalytic activity. Catalytic activity of GO@H-Pd0.10/Fe0.90 was 475 times more than that of GO@H-Pd due to the ordered catalytic monolayer immobilized on GO, proper ratio of Pd/Fe and the synergetic effect between Pd(II) and Fe(III) which could form active cluster containing Pd and Fe. The Pd(II) could be made more negative by transferring electron from GO to Fe(III) via ligand and then to Pd, improving its catalytic activity since it was easy for oxide addition. It also exhibited better stability and recyclability at least 8 times due to proper functional ligand and support. Deactivation mechanism was confirmed to be the aggregation of active centre during the recycling. Heterogeneous catalytic mechanism was also proved by poison test, hot filtration and ReactIR. The results of ReactIR presented different dynamic catalytic process for GO@H-Pd0.10Fe0.90 and homogeneous catalyst (Li2PdCl4/FeCl3·6H2O).The activation energies were 9.7 KJ/mol and 3.7 KJ/mol obtained for heterogeneous and homogeneous catalyst, respectively. Considering the diffusion effect, the factor of supports on the activity was also investigated by ReactIR, with which that GO@H-Pd0.10Fe0.90 catalytic activity was higher than that of homogeneous catalyst could be confirmed.