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2-Methylpyridine - Standard for GC,≥99.5%(GC), high purity , CAS No.109-06-8
Basic Description
Synonyms
Z104472800 | DTXCID001899 | RCRA waste no. U191 | .alpha.-Methylpyridine | EINECS 203-643-7 | Picoline, .alpha. | EC 203-643-7 | Picoline | PICOLINE, ALPHA | F0001-0192 | Pyridine, 2-methyl- | 2-Mepy | BCP26524 | DTXSID9021899 | Pyridine-2,3,4,5-d4,6-(met
Specifications & Purity
Standard for GC, ≥99.5%(GC)
Storage Temp
Protected from light,Room temperature,Argon charged
Shipped In
Normal
Grade
Standard for GC
Product Description
2-Picoline (2-Methylpyridine) was used to study the electron and proton transfer reactions of lumiflavin using Fourier transform ion cyclotron resonance mass spectrometry.
2-Picoline was used in the synthetic pathway for the production of dearomatized, allylated and C-H bond activated pyridine derivatives.
Taxonomic Classification
Kingdom
Organic compounds
Superclass
Organoheterocyclic compounds
Class
Pyridines and derivatives
Subclass
Methylpyridines
Intermediate Tree Nodes
Not available
Direct Parent
Methylpyridines
Alternative Parents
Heteroaromatic compounds Azacyclic compounds Organopnictogen compounds Organonitrogen compounds Hydrocarbon derivatives
Molecular Framework
Aromatic heteromonocyclic compounds
Substituents
Methylpyridine - Heteroaromatic compound - Azacycle - Organic nitrogen compound - Organopnictogen compound - Hydrocarbon derivative - Organonitrogen compound - Aromatic heteromonocyclic compound
Description
This compound belongs to the class of organic compounds known as methylpyridines. These are organic compounds containing a pyridine ring substituted at one or more positions by a methyl group.
External Descriptors
methylpyridine
Data sources
1. Djoumbou Feunang Y, Eisner R, Knox C, Chepelev L, Hastings J, Owen G, Fahy E, Steinbeck C, Subramanian S, Bolton E, Greiner R, and Wishart DS. ClassyFire: Automated Chemical Classification With A Comprehensive, Computable Taxonomy. Journal of Cheminformatics, 2016, 8:61.
Associated Targets(Human)
Associated Targets(non-human)
Mechanisms of Action
Mechanism of Action
Action Type
target ID
Target Name
Target Type
Target Organism
Binding Site Name
References
Names and Identifiers
IUPAC Name
2-methylpyridine
INCHI
InChI=1S/C6H7N/c1-6-4-2-3-5-7-6/h2-5H,1H3
InChIKey
BSKHPKMHTQYZBB-UHFFFAOYSA-N
Smiles
CC1=CC=CC=N1
Isomeric SMILES
CC1=CC=CC=N1
WGK Germany
1
RTECS
TJ4900000
UN Number
2313
Packing Group
III
Molecular Weight
93.13
Beilstein
104581
Reaxy-Rn
104581
Reaxys-RN_link_address
https://www.reaxys.com/reaxys/secured/hopinto.do?context=S&query=IDE.XRN=104581&ln=
Certificates(CoA,COO,BSE/TSE and Analysis Chart)
Chemical and Physical Properties
Solubility
It is miscible with water and soluble in most organic solvents.
Sensitivity
Light sensitive;Air sensitive
Refractive Index
1.501
Flash Point(°F)
29.4℃
Flash Point(°C)
29.4℃
Boil Point(°C)
128-129°C
Melt Point(°C)
-70°C
Molecular Weight
93.130 g/mol
XLogP3
1.100
Hydrogen Bond Donor Count
0
Hydrogen Bond Acceptor Count
1
Rotatable Bond Count
0
Exact Mass
93.0578 Da
Monoisotopic Mass
93.0578 Da
Topological Polar Surface Area
12.900 Ų
Heavy Atom Count
7
Formal Charge
0
Complexity
52.100
Isotope Atom Count
0
Defined Atom Stereocenter Count
0
Undefined Atom Stereocenter Count
0
Defined Bond Stereocenter Count
0
Undefined Bond Stereocenter Count
0
The total count of all stereochemical bonds
0
Covalently-Bonded Unit Count
1
Citations of This Product
1.
Guo Qiang, Lin Jinyuan, Yang Pengju, Jiang Yong, Zhang Binchuan, Zhu Longxin, Wang Xunqiu.
(2023)
Isobaric Vapor–Liquid Equilibrium for Binary System of 2-Methylpyridine + 2-Vinylpyridine at (1.9, 4.0 and 5.3) kPa. JOURNAL OF SOLUTION CHEMISTRY,
52
(8):
(921-939).
2.
Zhengyu Wang, Yufeng Hu, Zhiduo Ding, Hao Zhou, Jianye Zhang, Jingjing Zhan, Minghuo Wu.
(2023)
Determination of Organic Nitrogen Compounds in Gasoline by Water-Assisted Dispersive Solid-Phase Extraction (DSPE) and High-Performance Liquid Chromatography-High-Resolution Mass Spectrometry (HPLC-HRMS). ANALYTICAL LETTERS,
3.
Guangzhi Xu, Zhuoheng Tu, Xingbang Hu, Mian Li, Xiaomin Zhang, Youting Wu.
(2023)
Protic Brønsted acidic ionic liquids with variable acidity for efficient conversion of xylose and hemicellulose to furfural. FUEL,
339
(127334).
4.
Qingmei Chen, Xiujun Peng, Jingwen Xue, Jinjin Li, Chunfeng Pan.
(2022)
Identification and Quantification of Organic Contaminants and Evaluation of Their Effects on Amine Foaming in the Natural Gas Sweetening Industry. ACS Omega,
7
(50):
(46421–46427).
5.
Dongyuan Yang, Yanjun Min, Baihui Feng, Xueming Yang, Guorong Wu.
(2022)
Vibrational-state dependent decay dynamics of 2-pyridone excited to the S1 electronic state. PHYSICAL CHEMISTRY CHEMICAL PHYSICS,
24
(37):
(22710-22715).
6.
Bingbing Luo, Kai Wu, Jiajun Yu, Siyu Wang, Yihan Wang, Chenyang Chu, Huiyan Zhang.
(2022)
Enhancement of renewable N-heterocycles production via catalytic co-pyrolysis of glycerol and cellulose over HZSM-5 under ammonia atmosphere. JOURNAL OF ANALYTICAL AND APPLIED PYROLYSIS,
167
(105649).
7.
Pengfei Li, Dawei Shang, Wenhui Tu, Shaojuan Zeng, Yi Nie, Lu Bai, Haifeng Dong, Xiangping Zhang.
(2020)
NH3 absorption performance and reversible absorption mechanisms of protic ionic liquids with six-membered N-heterocyclic cations. SEPARATION AND PURIFICATION TECHNOLOGY,
248
(117087).
8.
Rongxing Qiu, Xiaoyan Luo, Le Yang, Jiaran Li, Xiaoyan Chen, Cheng Peng, Jinqing Lin.
(2020)
Regulated Threshold Pressure of Reversibly Sigmoidal NH3 Absorption Isotherm with Ionic Liquids. ACS Sustainable Chemistry & Engineering,
8
(3):
(1637–1643).
9.
Xin Zhang, Ziguo Yuan, Qian Yao, Ying Zhang, Yao Fu.
(2019)
Catalytic fast pyrolysis of corn cob in ammonia with Ga/HZSM-5 catalyst for selective production of acetonitrile. BIORESOURCE TECHNOLOGY,
290
(121800).
10.
Zhao Shuxue, Hu Chunhui, Guo Lizhong, Li Kuiran, Yu Hao.
(2019)
Isolation of a 3-hydroxypyridine degrading bacterium, Agrobacterium sp. DW-1, and its proposed degradation pathway. AMB Express,
9
(1):
(1-9).
11.
Ziguo Yuan, Xin Zhang, Qian Yao, Ying Zhang, Yao Fu.
(2019)
Production of acetonitrile via catalytic fast pyrolysis of biomass derived polylactic acid under ammonia atmosphere. JOURNAL OF ANALYTICAL AND APPLIED PYROLYSIS,
140
(376).
12.
Lujiang Xu, Qian Yao, Ying Zhang, Yao Fu.
(2016)
Producing pyridines via thermo-catalytic conversion and ammonization of glycerol over nano-sized HZSM-5. RSC Advances,
6
(89):
(86034-86042).
13.
Muhan Liang, Kangnan Wang, Ruifang Guan, Zhiqiang Liu, Duxia Cao, Qianqian Wu, Yanyan Shan, Yongxiao Xu.
(2016)
Several hemicyanine dyes as fluorescence chemosensors for cyanide anions. SPECTROCHIMICA ACTA PART A-MOLECULAR AND BIOMOLECULAR SPECTROSCOPY,
160
(34).
14.
Duan-Jian Tao, Zhang-Min Li, Zheng Cheng, Na Hu, Xiang-Shu Chen.
(2012)
Kinetics Study of the Ketalization Reaction of Cyclohexanone with Glycol Using Brønsted Acidic Ionic Liquids as Catalysts. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH,
51
(50):
(16263–16269).
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14 Citations
F2517074