2-甲氧基-4-甲基苯酚

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COA

级别和纯度:

≥98%(GC)

CAS编号: 93-51-6
分子式: C₈H₁₀O₂
分子量: 138.17
EC号: 202-252-9
MDL号: MFCD00002378
PubChem编号: 7144
PubChem SID: 488180311

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货号 (SKU)	包装规格	是否现货
M158094-5g	5g	现货
M158094-10g	10g	期货
M158094-25g	25g	现货
M158094-50g	50g	现货
M158094-100g	100g	现货
M158094-250g	250g	现货
M158094-500g	500g	现货
M158094-2.5kg	2.5kg	现货

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基本描述

别名	甲氧甲酚 \| 4-甲基愈创木酚 \| 2-甲氧基对甲苯酚 \| 4-羟基-3-甲氧基甲苯 \| 2-羟基-5-甲基苯甲醚
英文别名	2-Methoxy-4-Methylphenol--d3,OD \| CHEBI:89886 \| 2-Methoxy-4-methylphenol, >=98% \| 4-Hydroxy-3-methoxy-1-methylbenzene \| 4-Methyl guaiacol \| 2-METHOXY-P- CRESOL \| 3-Methoxy-4-hydroxytoluene \| Q-100894 \| 2-Methoxy-4-methylphenol (creosol) \| FEMA 2671 \| Homo
规格或纯度	≥98%(GC)
英文名称	2-Methoxy-4-methylphenol
应用	It was used in preparation of renewable bis(cyanate) esters.
运输条件	常规运输
作用类型	抑制剂
产品介绍	It is the major component of black-ripe table olive aroma. It is the major anti-inflammatory compound in bamboo vinegar. Kinetics of reaction of 2-methoxy-4-methylphenol with chlorine atoms was studied.It was used in preparation of renewable bis(cyanate) esters. It is the major component of black-ripe table olive aroma. It is the major anti-inflammatory compound in bamboo vinegar. Kinetics of reaction of 2-methoxy-4-methylphenol with chlorine atoms was studied. It was used in preparation of renewable bis(cyanate) esters.
纯度	≥98%(GC)

名称和识别符

PubChem SID	488180311
EC号	202-252-9
分子类型	小分子
IIUPAC Name	2-methoxy-4-methylphenol
INCHI	1S/C8H10O2/c1-6-3-4-7(9)8(5-6)10-2/h3-5,9H,1-2H3
InChi Key	PETRWTHZSKVLRE-UHFFFAOYSA-N
Smiles	CC1=CC(=C(C=C1)O)OC
Isomeric SMILES	CC1=CC(=C(C=C1)O)OC
分子量	138.17
Reaxy-Rn	1862340
Reaxys-RN link address	https://www.reaxys.com/reaxys/secured/hopinto.do?context=S&query=IDE.XRN=1862340&ln=

化学和物理性质

溶解性	Slightly soluble in water.
密度	1.095
折光率	1.54
闪点(℉)	210.2 °F
闪点(℃)	99°C(lit.)
沸点	221°C(lit.)
熔点	5°C(lit.)
分子量	138.160 g/mol
XLogP3	1.300
氢键供体数Hydrogen Bond Donor Count	1
氢键受体数Hydrogen Bond Acceptor Count	2
可旋转键计数Rotatable Bond Count	1
精确质量Exact Mass	138.068 Da
单同位素质量Monoisotopic Mass	138.068 Da
拓扑极表面积Topological Polar Surface Area	29.500 Å²
重原子数Heavy Atom Count	10
形式电荷Formal Charge	0
复杂度Complexity	103.000
同位素原子数Isotope Atom Count	0
定义的原子立体中心计数Defined Atom Stereocenter Count	0
未定义的原子立体中心计数Undefined Atom Stereocenter Count	0
定义的键立体中心计数Defined Bond Stereocenter Count	0
未定义的键立体中心计数Undefined Bond Stereocenter Count	0
所有立体化学键的总数The total count of all stereochemical bonds	0
共价键合单元计数Covalently-Bonded Unit Count	1

安全和危险性（GHS）

象形图	GHS07
信号词	警告
危险声明	H302: 吞食有害 H315: 引起皮肤刺激 H317: 可能引起皮肤过敏反应 H319: 引起严重眼睛刺激
预防措施声明	P261: 避免吸入灰尘/烟雾/气体/雾/蒸汽/喷雾 P264: 处理后要彻底洗手。 P270: 使用本产品时，请勿进食、饮水或吸烟。 P272: 被污染的工作服不允许离开工作场所 P280: 戴防护手套/穿防护服/戴防护眼罩/戴防护面具。 P321: 特殊处理（请参阅此标签上的...）。 P330: 漱口 P302+P352: 如皮肤沾染：用水充分清洗。 P305+P351+P338: 如进入眼睛：用水小心冲洗几分钟。如戴隐形眼镜并可方便地取出，取出隐形眼镜。继续冲洗。 P333+P313: 如发生皮肤刺激或皮疹：求医/就诊。 P362+P364: 脱掉沾污的衣服，清洗后方可重新使用。 P501: 将内容物/容器处理到。。。 P264+P265: 处理后彻底洗手[和…]。不要触摸眼睛。 P301+P317: 如果被吞咽：请寻求医疗帮助。 P337+P317: 如果眼睛刺激持续：寻求医疗帮助。 P332+P317: 如果出现皮肤刺激：请寻求医疗帮助。
WGK Germany	3
RTECS	GP1755000
Merck Index	2571
个人防护装备	Eyeshields， Faceshields， full-face respirator (US)， Gloves， multi-purpose combination respirator cartridge (US)， type ABEK (EN14387) respirator filter

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批号(Lot Number)	证书类型	货号
K2103077	分析证书	M158094
K2103078	分析证书	M158094
K2103080	分析证书	M158094
G2518052	分析证书	M158094
B2226228	分析证书	M158094
B2226230	分析证书	M158094
B2226232	分析证书	M158094
B2226233	分析证书	M158094
B2226327	分析证书	M158094
D2108295	分析证书	M158094
K2415605	分析证书	M158094
K2415609	分析证书	M158094
B2313024	分析证书	M158094
B2226216	分析证书	M158094
B2226236	分析证书	M158094
A2423029	分析证书	M158094
J2415105	分析证书	M158094
F2511177	分析证书	M158094
L2301105	分析证书	M158094

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引用文献

1. Xuewu Ji, Guirong Bao, Peng Gao, Jia Luo, Dequan Chen, Zhen Fang. (2024) Hydrodeoxygenation of vanillin to 2-methoxy-4-methylphenol over carbon dots supported Pd catalyst. Molecular Catalysis, 553 (113722). [10.1016/j.mcat.2023.113722]
2. Zhipeng Tian, Xiaoxin Chen, Tao Liu, Junyao Wang, Chao Wang, Riyang Shu, Jianping Liu, Ying Chen. (2023) Highly efficient Co-based catalysts supported on K-modified alumina for selective hydrodeoxygenation of lignin-derived phenols to alkyl cyclohexanols. RENEWABLE ENERGY, 218 (119304). [10.1016/j.renene.2023.119304]
3. Ji Mi, Cui Ye, Yongsheng Guo, Wenjun Fang. (2023) Strategical design of bridged vanillic Schiff-bases as jet fuel antioxidants. FUEL, 351 (128834). [10.1016/j.fuel.2023.128834]
4. Jiahui Li, Haiyang Zhao, Qi Cao, Wenguang Zeng, Jiangjiang Zhang, Yujie Guo, Yi Zhao, Xigao Jian, Zhihuan Weng. (2023) Synthesis of Cyano-Containing Epoxy Precursor from Vanillin for Engineering Multifaceted Performance-Enhancing Resins. ACS Sustainable Chemistry & Engineering, 11 (26): (9528–9539). [10.1021/acssuschemeng.2c06678]
5. Xin Zhang, Jingyun Jiang, Hao Li. (2023) Critical role of support crystal structures on highly selective hydrodeoxygenation of lignin-derived vanillin over Pd/ZrO2 catalysts. FUEL PROCESSING TECHNOLOGY, 249 (107844). [10.1016/j.fuproc.2023.107844]
6. Hao Xu, Hao Li. (2023) Regulating the crystal phase of Pd/Nb2O5 for vanillin selective HDO at room temperature. JOURNAL OF CATALYSIS, 423 (105). [10.1016/j.jcat.2023.04.010]
7. Shasha Tang, Haidan Lin, Kai Dong, Jun Zhang, Chengji Zhao. (2023) Closed-loop recycling and degradation of guaiacol-based epoxy resin and its carbon fiber reinforced composites with S-S exchangeable bonds. POLYMER DEGRADATION AND STABILITY, 210 (110298). [10.1016/j.polymdegradstab.2023.110298]
8. Zhuojie Zhong, Bowen Luo, Chengyin Lin, Tao Yin, Zhipeng Tian, Chao Wang, Ying Chen, Yanxue Wu, Riyang Shu. (2023) Ultrafast microfluidic preparation of highly dispersed Ru/TiO2 catalyst for the hydrodeoxygenation of lignin-derived phenolic compounds. FUEL, 340 (127567). [10.1016/j.fuel.2023.127567]
9. Baoyu Wang, Peng Zhou, Ximing Yan, Hu Li, Hongguo Wu, Zehui Zhang. (2023) Cooperative catalysis of Co single atoms and nanoparticles enables selective CAr−OCH3 cleavage for sustainable production of lignin-based cyclohexanols. Journal of Energy Chemistry, 79 (535). [10.1016/j.jechem.2022.12.020]
10. Tao Liu, Zhipeng Tian, Weijie Zhang, Bowen Luo, Libin Lei, Chao Wang, Jianping Liu, Riyang Shu, Ying Chen. (2023) Selective hydrodeoxygenation of lignin-derived phenols to alkyl cyclohexanols over highly dispersed RuFe bimetallic catalysts. FUEL, 339 (126916). [10.1016/j.fuel.2022.126916]
11. Dongpo He, Jingyu Xu, Yanzhu Guo, Mengtian Yu, Qingyu Wang, Jinghui Zhou, Xing Wang. (2022) RuNi nanoparticles embedded in N-doped carbon nanofibers as a bimetallic catalyst for the hydrogenolysis of peanut shell lignin. FUEL PROCESSING TECHNOLOGY, 238 (107519). [10.1016/j.fuproc.2022.107519]
12. Zegang Qiu, Xiaoxia He, Zhiqin Li, Qichen Guan, Liang Ding, Yanan Zhu, Yueling Cao. (2022) CoZn/N-Doped porous carbon derived from bimetallic zeolite imidazolate framework/g-C3N4 for efficient hydrodeoxygenation of vanillin. Catalysis Science & Technology, 12 (16): (5178-5188). [10.1039/D2CY00642A]
13. Jiang Zhang, Zijian Wang, Mugeng Chen, Yifeng Zhu, Yongmei Liu, Heyong He, Yong Cao, Xinhe Bao. (2022) N-doped carbon layer-coated Au nanocatalyst for H2-free conversion of 5-hydroxymethylfurfural to 5-methylfurfural. CHINESE JOURNAL OF CATALYSIS, 43 (2212). [10.1016/S1872-2067(21)64049-4]
14. Junjun Yin, Xiaoqian Chen, Duo Wang. (2022) Purification of creosol applying green heterogeneous extraction technology. JOURNAL OF CHEMICAL TECHNOLOGY AND BIOTECHNOLOGY, 97 (10): (2945-2951). [10.1002/jctb.7169]
15. Jiansu Ran, Lujain Alfilfil, Jingwei Li, Ruixue Yangcheng, Zhaohui Liu, Qin Wang, Yuntong Cui, Tong Cao, Min Qiao, Kexin Yao, Daliang Zhang, Jianjian Wang. (2022) Tailoring interfacial microenvironment of palladium-zeolite catalysts for the efficient low-temperature hydrodeoxygenation of vanillin in water. ChemCatChem, 14 (14): (e202200397). [10.1002/cctc.202200397]
16. Liu Mengfan, Yao Jingjing, Zhang Chengliang, Hao Runqin, Zhang Zhongguo, Cao Wenbo. (2022) Quantitative analysis of multi-components by single-marker: An effective method for the chemical characterization of wood vinegar. INDUSTRIAL CROPS AND PRODUCTS, 182 (114862). [10.1016/j.indcrop.2022.114862]
17. Yinan Sun, Zeying Zhou, Hao Jiang, Yuting Duan, Jialin Li, Xiaoqiu Liu, Lihua Hong, Chengji Zhao. (2022) Preparation and evaluation of novel bio-based Bis-GMA-free dental composites with low estrogenic activity. DENTAL MATERIALS, 38 (281). [PMID:34955233] [10.1016/j.dental.2021.12.010]
18. Lu Xiaowen, Guo Chunmu, Zhang Mingyang, Leng Leipeng, Horton J. Hugh, Wu Wei, Li Zhijun. (2021) Rational design of palladium single-atoms and clusters supported on silicoaluminophosphate-31 by a photochemical route for chemoselective hydrodeoxygenation of vanillin. Nano Research, 14 (11): (4347-4355). [10.1007/s12274-021-3857-2]
19. Dongdong Wang, Wanbing Gong, Jifang Zhang, Miaomiao Han, Chun Chen, Yunxia Zhang, Guozhong Wang, Haimin Zhang, Huijun Zhao. (2021) Encapsulated Ni-Co alloy nanoparticles as efficient catalyst for hydrodeoxygenation of biomass derivatives in water. CHINESE JOURNAL OF CATALYSIS, 42 (2027). [10.1016/S1872-2067(21)63828-7]
20. Zhijun Li, Xiaowen Lu, Weiwei Sun, Leipeng Leng, Mingyang Zhang, Honghong Li, Lu Bai, Dundong Yuan, J. Hugh Horton, Qian Xu, Jun Wang. (2021) One-step synthesis of single palladium atoms in WO2.72 with high efficiency in chemoselective hydrodeoxygenation of vanillin. APPLIED CATALYSIS B-ENVIRONMENTAL, 298 (120535). [10.1016/j.apcatb.2021.120535]
21. Mingxing Duan, Qingyan Cheng, Mingming Wang, Yanji Wang. (2021) In situ hydrodeoxygenation of vanillin over Ni–Co–P/HAP with formic acid as a hydrogen source. RSC Advances, 11 (18): (10996-11003). [PMID:35423576] [10.1039/D1RA00979F]
22. Jindong Wang, Wenzhi Li, Huizhen Wang, Ajibola Temitope Ogunbiyi, Xiaomeng Dou, Qiaozhi Ma. (2020) Effects of the novel catalyst Ni–S2O82−–K2O/TiO2 on efficient lignin depolymerization. RSC Advances, 10 (14): (8558-8567). [PMID:35497830] [10.1039/C9RA10675H]
23. Jingjing Zhang, Qingli Qian, Ying Wang, Bernard Baffour Asare Bediako, Jiang Yan, Buxing Han. (2019) Synthesis of ethanol from aryl methyl ether/lignin, CO2 and H2. Chemical Science, 10 (45): (10640-10646). [PMID:32110349] [10.1039/C9SC03386F]
24. Bingxing Jiang, Jun Hu, Yiheng Qiao, Xiaoxiang Jiang, Ping Lu. (2019) Depolymerization of Lignin over a Ni–Pd Bimetallic Catalyst Using Isopropanol as an in Situ Hydrogen Source. ENERGY & FUELS, 33 (9): (8786–8793). [10.1021/acs.energyfuels.9b01976]
25. Wenjing Song, Shijie Zhou, Shihua Hu, Weikun Lai, Yixin Lian, Jianqiang Wang, Weimin Yang, Meiyu Wang, Peng Wang, Xingmao Jiang. (2019) Surface Engineering of CoMoS Nanosulfide for Hydrodeoxygenation of Lignin-Derived Phenols to Arenes. ACS Catalysis, 9 (1): (259–268). [10.1021/acscatal.8b03402]
26. Lisha Zhao, Xinping Ouyang, Guanfeng Ma, Yong Qian, Xueqing Qiu, Tao Ruan. (2018) Improving antioxidant activity of lignin by hydrogenolysis. INDUSTRIAL CROPS AND PRODUCTS, 125 (228). [10.1016/j.indcrop.2018.09.002]
27. Jun Hu, Shiliang Wu, Xiaoxiang Jiang, Rui Xiao. (2018) Structure–Reactivity Relationship in Fast Pyrolysis of Lignin into Monomeric Phenolic Compounds. ENERGY & FUELS, 32 (2): (1843–1850). [10.1021/acs.energyfuels.7b03593]
28. Xinping Ouyang, Guodian Zhu, Xiangzhen Huang, Xueqing Qiu. (2015) Microwave assisted liquefaction of wheat straw alkali lignin for the production of monophenolic compounds. Journal of Energy Chemistry, 24 (72). [10.1016/S2095-4956(15)60286-8]
29. Xiaohua Li, Zhitao Lei, Yu Cao, Shanshan Shao, Shiliang Wu. (2025) Aqueous-phase hydrogenation of various lignin-derived phenols to cycloketones as platform compounds over Br modified metal-acid mixed catalyst. ENERGY, (135025). [10.1016/j.energy.2025.135025]
30. Xiao Jia, Hongli Cui, Song Qin, Jingnan Ren, Zhifeng Zhang, Qi An, Nawei Zhang, Jinchu Yang, Yongfeng Yang, Gang Fan, Siyi Pan. (2024) Characterizing and decoding the key odor compounds of Spirulina platensis at different processing stages by sensomics. FOOD CHEMISTRY, 461 (140944). [PMID:39182338] [10.1016/j.foodchem.2024.140944]
31. Shichao Su, Yaqiao Tian, Huifeng Li, Weiyao Yang, Hongda Zhang, Feng Liu, Le Sang. (2025) Hydrogenation of vanillin to vanillyl alcohol over Pd/PDA/Ni foam in micropacked bed reactors. Chemical Engineering and Processing-Process Intensification, (110262). [10.1016/j.cep.2025.110262]
32. Siyi Mi, Lungang Chen, Xinghua Zhang, Qi Zhang, Longlong Ma, Jianguo Liu. (2024) Selective hydrogenation of vanillin over a graphene-encapsulated nitrogen-doped bimetallic magnetic Ni/Fe@NDC nano-catalyst. RSC Advances, 14 (24): (16747-16757). [PMID:38784407] [10.1039/D4RA02729A]
33. Jianjun Wang, Bao Zhang, Hang Xun, Xi Yao, Feng Tang. (2024) Simultaneous Quantification of Twelve Compounds from Bamboo/Wood Vinegar by Gas Chromatography-Mass Spectrometry. Separations, 11 (6): (168). [10.3390/separations11060168]
34. Xia Zhang, Wenzhi Li, Yihang Jiang, Leyu Zhu, Liqun Wang. (2024) Valorization of waste lignin: Efficient and steady production of liquid fuels. INDUSTRIAL CROPS AND PRODUCTS, 220 (119400). [10.1016/j.indcrop.2024.119400]
35. Xiaohong Ren, Qian Qiang, Zhuohua Sun, Ting Wei, Xiaoqiang Yu, Zeming Rong, Changzhi Li. (2024) Water Splitting Integrated with Self-Transfer Hydrogenolysis for Efficient Demethoxylation of Guaiacols to Phenols over the Ni/MgO Catalyst. ACS Catalysis, 14 (7): (5247-5259). [10.1021/acscatal.4c00038]

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