基本描述

别名	氯化四甲基铵
英文别名	TETRAMETHYLAMMONIUM CHLORIDE \| 75-57-0 \| Tetramethyl ammonium chloride \| Tetramine chloride \| USAF AN-8 \| Methanaminium, N,N,N-trimethyl-, chloride \| N,N,N-Trimethylmethanaminium chloride \| 9050-97-9 \| tetramethylazanium chloride \| Ammonium, tetramethyl-, chloride \| tetramet
规格或纯度	用于分子生物学, ≥99%(AT)
英文名称	Tetramethylammonium chloride
应用	极谱分析试剂。
储存温度	干燥
运输条件	常规运输
产品介绍	易挥发。易吸湿。于230℃以上分解为三甲胺和氯甲烷。易溶于甲醇，溶于水和热乙醇，不溶于乙醚和氯仿。有毒，半数致死量(小鼠，腹腔)25mg/kg。有刺激性。极谱分析试剂。

关联靶点（人）

SLC22A1 Tchem Solute carrier family 22 member 1 (646 活性数据)

点击查看靶蛋白信息： SLC22A1

活性类型	Relation	Activity value	Units	Action Type	期刊	PubMed Id	doi	Assay Aladdin ID

SLC22A2 Tchem Solute carrier family 22 member 2 (261 活性数据)

点击查看靶蛋白信息： SLC22A2

活性类型	Relation	Activity value	Units	Action Type	期刊	PubMed Id	doi	Assay Aladdin ID

关联靶点（其它种属）

Slc5a7 Choline transporter (45 活性数据)

点击查看靶蛋白信息： Slc5a7

活性类型	Relation	Activity value	Units	Action Type	期刊	PubMed Id	doi	Assay Aladdin ID

Slc22a5 Solute carrier family 22 member 5 (44 活性数据)

点击查看靶蛋白信息： Slc22a5

活性类型	Relation	Activity value	Units	Action Type	期刊	PubMed Id	doi	Assay Aladdin ID

Slc22a3 Solute carrier family 22 member 3 (35 活性数据)

点击查看靶蛋白信息： Slc22a3

活性类型	Relation	Activity value	Units	Action Type	期刊	PubMed Id	doi	Assay Aladdin ID

作用机制

作用机制	Action Type	target ID	Target Name	Target Type	Target Organism	Binding Site Name	参考文献

名称和识别符

EC号	200-880-8
分子类型	小分子
IUPAC Name	tetramethylazanium;chloride
INCHI	InChI=1S/C4H12N.ClH/c1-5(2,3)4;/h1-4H3;1H/q+1;/p-1
InChi Key	OKIZCWYLBDKLSU-UHFFFAOYSA-M
Canonical SMILES	C[N+](C)(C)C.[Cl-]
Isomeric SMILES	C[N+](C)(C)C.[Cl-]
WGK Germany	1
PubChem CID	6379
分子量	109.6
Beilstein号	3911201

化学和物理性质

熔点	> 300 °C
分子量	109.600 g/mol
XLogP3
氢键供体数Hydrogen Bond Donor Count	0
氢键受体数Hydrogen Bond Acceptor Count	1
可旋转键计数Rotatable Bond Count	0
精确质量Exact Mass	109.066 Da
单同位素质量Monoisotopic Mass	109.066 Da
拓扑极表面积Topological Polar Surface Area	0.000 Å²
重原子数Heavy Atom Count	6
形式电荷Formal Charge	0
复杂度Complexity	19.100
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	2

安全和危险性（GHS）

象形图	GHS06, GHS08, GHS09, GHS07
信号词	Danger
危险声明	H315: 引起皮肤刺激 H319: 引起严重眼睛刺激 H335: 可能引起呼吸道刺激 H301: 吞咽会中毒 H311: 皮肤接触有毒 H411: 对水生生物有毒并具有长期持续影响 H312: 皮肤接触有害 H300: 吞咽致命 H370: 对器官造成损害
预防措施声明	P261: 避免吸入灰尘/烟雾/气体/雾/蒸汽/喷雾 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。 P273: 避免释放到环境中。 P280: 戴防护手套/穿防护服/戴防护眼罩/戴防护面具。 P302+P352: 如皮肤沾染：用水充分清洗。 P321: 特殊处理（请参阅此标签上的...）。 P405: 密闭存放 P501: 将内容物/容器处理到。。。 P264: 处理后要彻底洗手。 P260: 不要吸入灰尘/烟雾/气体/雾/蒸汽/喷雾。 P271: 仅在室外或通风良好的地方使用。 P270: 使用本产品时，请勿进食、饮水或吸烟。 P304+P340: 如误吸入：将人转移到空气新鲜处，保持呼吸舒适体位。 P403+P233: 存放在通风良好的地方。保持容器密闭。 P362+P364: 脱掉沾污的衣服，清洗后方可重新使用。 P391: 收集溢出物 P330: 漱口 P361+P364: 立即脱掉所有沾染的衣服，清洗后方可重新使用。 P264+P265: 处理后彻底洗手[和…]。不要触摸眼睛。 P301+P316: 如果吞咽：立即寻求紧急医疗救助。 P317: 寻求紧急医疗救助。 P337+P317: 如果眼睛刺激持续：寻求医疗帮助。 P308+P316: 如果暴露或担心：立即寻求紧急医疗救助。 P332+P317: 如果出现皮肤刺激：请寻求医疗帮助。 P316: 立即寻求紧急医疗救助。 P319: 如果你感到不适，请寻求医疗帮助。
WGK Germany	1
个人防护装备	Eyeshields, Faceshields, Gloves, type P2 (EN 143) respirator cartridges

SDS英文版

质量标准

Strontium(Sr)	0-5（ppm）
UV Absorbance 260nm	0-0.02
Chromium (ICP)	0-5（ppm）
Sodium(ICP)	0-50（ppm）
Arsenic traces(MHS-AAS)	0-0.1（ppm）
Cobalt(ICP)	0-5（ppm）
Total sulfur as SO4 (ICP)	0-50（ppm）
Copper(ICP)	0-5（ppm）
Potassium(K)(ICP)	0-50（ppm）
Magnesium (Mg)	0-5（ppm）
Lithium (ICP)	0-5（ppm）
Barium (ICP)	0-5（ppm）
Zinc(ICP)	0-5（ppm）
Calcium (Ca)	0-10（ppm）
Manganese(ICP)	0-5（ppm）
Nickel(ICP)	0-5（ppm）
Iron(ICP)	0-5（ppm）
Molybdenum (ICP)	0-5（ppm）
UV Absorbance 280nm	0-0.02
Cadmium(Cd)	0-5（ppm）
Bismuth (ICP)	0-5（ppm）
Lead (ICP)	0-5（ppm）
Dimethyl Sulfoxide(NMR)	0-5（ppm）
(Br)Bromide	0-500（ppm）
Purity(Titration by AgNO3)	99-101（%）
Appearance（T139946)	Colorless or White Powder or Crystals
DNAse, RNAse, Protease, Phosphatase	None Detected
Proton NMR spectrum	Conforms to Structure
Residue (filter test)	no residue
Solubility(6.57g in 10ml water, Colorless Clear)	Pass

质量标准

质检证书（CoA,COO,BSE/TSE 和分析图谱)

C of A & Other Certificates(BSE/TSE, COO):

输入批号以搜索分析图谱:

通过匹配包装上的批号来查找并下载产品的 COA，每批产品都进行了严格的验证，您可放心使用！

找到9个结果

批号(Lot Number)	证书类型	日期	货号
D2417585	分析证书	24-01-23	T139946
D2417587	分析证书	24-01-23	T139946
D2417584	分析证书	24-01-23	T139946
D2417586	分析证书	24-01-23	T139946
B2320583	分析证书	23-01-30	T139946
B2320644	分析证书	23-01-30	T139946
B1918059	分析证书	22-12-09	T139946
C2223438	分析证书	22-03-07	T139946
C2223439	分析证书	22-03-07	T139946

此产品的引用文献

如何在您的发表作品中引用阿拉丁的产品和网站?

1. Zaichao Guo, Fujin Li, Xuanxuan Wu, Zhihao Liang, Muhammad Junaid, Jianjun Xie, Liang Lu, Jinglai Duan, Jie Liu, Huijun Yao. (2024) Efficient ion sieving and ion transport properties in sub-nanoporous polyetherimide membranes. DESALINATION, 573 (117192). [10.1016/j.desal.2023.117192]
2. Huidong Tang, Yanqiao Xu, Xiaobo Hu, Haijie Chen, Sanhai Wang, Weihui Jiang, Qing Hu, Lianjun Wang, Wan Jiang. (2023) Scalable Synthesis of Lead-Free Tetramethylammonium Manganese Halides for Highly Efficient Backlight Displays. Laser & Photonics Reviews, 18 (1): (2300672). [10.1002/lpor.202300672]
3. Shen Lingqi, Jin Xiangzi, Zhang Zhihui, Yi Yuexing, Zhang Jingyu, Li Zuguang. (2023) Extraction of Eugenol from Essential Oils by In Situ Formation of Deep Eutectic Solvents: A Green Recyclable Process. Journal of Analysis and Testing, (1-11). [10.1007/s41664-023-00267-x]
4. Weiwei Zhang, Leyu Dai, Tao Sun, Chuanxiang Qin, Jianjun Wang, Jun Sun, Lixing Dai. (2023) A transparent, self-adhesive and fully recyclable conductive PVA based hydrogel for wearable strain sensor. POLYMER, 283 (126281). [10.1016/j.polymer.2023.126281]
5. Xiang-Yu Wang, Ming-Wei Zhao, Xu-Hao Wang, Peng Liu, Meng-Yao Fan, Teng Li, Zhen-Feng Ma, Ying-Jie Dai, Cai-Li Dai. (2023) Intermolecular interactions induced property improvement for clean fracturing fluid by deep eutectic solvents. Petroleum Science, [10.1016/j.petsci.2023.08.013]
6. Linsheng Wang, Yulou Cui, Jiangtao Li, Zhen Song, Hongye Cheng, Zhiwen Qi. (2023) Toward high-performance associative extraction by forming deep eutectic solvent: A component pairing and mechanism study. CHEMICAL ENGINEERING SCIENCE, 272 (118602). [10.1016/j.ces.2023.118602]
7. Zhong Yuan, Zhang Jiangwei, Li Tingting, Xu Wenwu, Yao Qiaofeng, Lu Min, Bai Xue, Wu Zhennan, Xie Jianping, Zhang Yu. (2023) Suppression of kernel vibrations by layer-by-layer ligand engineering boosts photoluminescence efficiency of gold nanoclusters. Nature Communications, 14 (1): (1-12). [PMID:36746958] [10.1038/s41467-023-36387-2]
8. Mengyuan Jin, Sheng Cheng, Zhuo Yang, Yutong Luo, Yanhui Guo. (2023) A novel high-voltage solid electrolyte of Na3B24H23 for 4 V all-solid-state sodium battery. CHEMICAL ENGINEERING JOURNAL, 455 (140904). [10.1016/j.cej.2022.140904]
9. Jianhua Song, Lin Xu, Xiaoping Wang, Chonghao Chen, Weichong Wang, Haoyu Long, Muhammad Asif Nawaz, Dianhua Liu. (2023) Tailored acidic deep eutectic solvents: A multifunctional co-catalyst mediating homogeneous catalysis and heterogeneous separation of ethylene methoxycarbonylation. FUEL, 333 (126562). [10.1016/j.fuel.2022.126562]
10. Wei-Wei Yan, Xian-Yong Wei, Jun Li, Meng-Xiao Wang, Hong-Cun Bai, Zhi-Min Zong. (2022) Priority Separation of Phenols with Deep Eutectic Solvents from an Acetonitrile-Extractable Portion of a Shale Oil: Experimental and Computational. ENERGY & FUELS, 36 (11): (5657–5665). [10.1021/acs.energyfuels.2c00403]
11. Mei Jiang, Lin Zhu, Qian Zhao, Guangyuan Chen, Zeru Wang, Jingjing Zhang, Ling Zhang, Jiehong Lei, Tao Duan. (2022) Novel synthesis of NaY-NH4F-Bi2S3 composite for enhancing iodine capture. CHEMICAL ENGINEERING JOURNAL, 443 (136477). [10.1016/j.cej.2022.136477]
12. Yang He, Lihua Zhou, Shaohua Gou, Xiaolin Qian, Zhihao Tian, Junwen Chen, Jie Liao, Jing Huo, Guangjun Gou. (2022) Imidazolium Gemini ionic liquids for regulating facilely the swelling and dispersion of montmorillonite in water. APPLIED CLAY SCIENCE, 219 (106457). [10.1016/j.clay.2022.106457]
13. Xinquan Liang, Yuan Zhu, Benkun Qi, Shiqian Li, Jianquan Luo, Yinhua Wan. (2021) Structure-property-performance relationships of lactic acid-based deep eutectic solvents with different hydrogen bond acceptors for corn stover pretreatment. BIORESOURCE TECHNOLOGY, 336 (125312). [PMID:34044243] [10.1016/j.biortech.2021.125312]
14. Zeping Wang, Dingli Xie, Feng Zhang, Jiabing Yu, Xianping Chen, Ching Ping Wong. (2020) Controlling information duration on rewritable luminescent paper based on hybrid antimony (III) chloride/small-molecule absorbates. Science Advances, 6 (48): [PMID:33239292] [10.1126/sciadv.abc2181]
15. Yaqing Wang, Wenjun Chen, Qi Zhao, Guizhen Jin, Zhimin Xue, Yingxiong Wang, Tiancheng Mu. (2020) Ionicity of deep eutectic solvents by Walden plot and pulsed field gradient nuclear magnetic resonance (PFG-NMR). PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 22 (44): (25760-25768). [PMID:33147302] [10.1039/D0CP01431A]
16. Zifei Yan, Jian Deng, Yuchao Chen, Guangsheng Luo. (2020) Preparation of 2,3-Epoxypropyl Neodecanoate: Process Optimization and Mechanism Discussion. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 59 (43): (19168–19176). [10.1021/acs.iecr.0c02906]
17. Qi Zhang, Siru Ren, Song Xue, Ang Li, Siyao Liu, Xiaodong Sun. (2021) Tetraalkylammonium-l-tartrate ionic liquids as sole chiral selectors in capillary electrophoresis. SEPARATION AND PURIFICATION TECHNOLOGY, 256 (117842). [10.1016/j.seppur.2020.117842]
18. Xuejiang Cheng, Xin Wang, Guangming Chen. (2018) A convenient and highly tunable way to n-type carbon nanotube thermoelectric composite film using common alkylammonium cationic surfactant. Journal of Materials Chemistry A, 6 (39): (19030-19037). [10.1039/C8TA07746K]
19. Youan Ji, Yucui Hou, Shuhang Ren, Muge Niu, Congfei Yao, Weize Wu. (2018) Efficient extraction of indole from wash oil by quaternary ammonium salts via forming deep eutectic solvents. FUEL, 215 (330). [10.1016/j.fuel.2017.10.057]
20. Yucui Hou, Jie Kong, Yuehong Ren, Shuhang Ren, Weize Wu. (2017) Mass transfer dynamics in the separation of phenol from model oil with quaternary ammonium salts via forming deep eutectic solvents. SEPARATION AND PURIFICATION TECHNOLOGY, 174 (554). [10.1016/j.seppur.2016.10.038]
21. Xiao Huang, Yaofang Xuan, Lisiqi Xie, Bin Su. (2016) Unraveling the Phase-Transfer Catalysis Mechanism of Oxygen Reduction Catalyzed by Iron(III) meso-tetra-(4-N-Methyl-pyridyl) Porphine at the Liquid/Liquid Interface. ChemElectroChem, 3 (11): (1781-1786). [10.1002/celc.201600480]
22. Youan Ji, Yucui Hou, Shuhang Ren, Congfei Yao, Weize Wu. (2016) Phase equilibria of high pressure CO2 and deep eutectic solvents formed by quaternary ammonium salts and phenol. FLUID PHASE EQUILIBRIA, 429 (14). [10.1016/j.fluid.2016.08.020]
23. Xiao Huang, Lisiqi Xie, Xingyu Lin, Bin Su. (2016) Permselective Ion Transport Across the Nanoscopic Liquid/Liquid Interface Array. ANALYTICAL CHEMISTRY, 88 (12): (6563–6569). [PMID:27240714] [10.1021/acs.analchem.6b01383]
24. Yaofang Xuan, Xiao Huang, Bin Su. (2015) Biomimetic Oxygen Reduction Reaction Catalyzed by Microperoxidase-11 at Liquid/Liquid Interfaces. Journal of Physical Chemistry C, 119 (21): (11685–11693). [10.1021/acs.jpcc.5b02131]
25. Hua Tan, Wenxia Liu, Dehai Yu, Haidong Li, Martin A. Hubbe, Bei Gong, Wei Zhang, Huili Wang, Guodong Li. (2014) ASA-in-water emulsions stabilized by laponite nanoparticles modified with tetramethylammonium chloride. CHEMICAL ENGINEERING SCIENCE, 116 (682). [10.1016/j.ces.2014.06.005]

参考文献

1. Zaichao Guo, Fujin Li, Xuanxuan Wu, Zhihao Liang, Muhammad Junaid, Jianjun Xie, Liang Lu, Jinglai Duan, Jie Liu, Huijun Yao. (2024) Efficient ion sieving and ion transport properties in sub-nanoporous polyetherimide membranes. DESALINATION, 573 (117192). [10.1016/j.desal.2023.117192]
2. Huidong Tang, Yanqiao Xu, Xiaobo Hu, Haijie Chen, Sanhai Wang, Weihui Jiang, Qing Hu, Lianjun Wang, Wan Jiang. (2023) Scalable Synthesis of Lead-Free Tetramethylammonium Manganese Halides for Highly Efficient Backlight Displays. Laser & Photonics Reviews, 18 (1): (2300672). [10.1002/lpor.202300672]
3. Shen Lingqi, Jin Xiangzi, Zhang Zhihui, Yi Yuexing, Zhang Jingyu, Li Zuguang. (2023) Extraction of Eugenol from Essential Oils by In Situ Formation of Deep Eutectic Solvents: A Green Recyclable Process. Journal of Analysis and Testing, (1-11). [10.1007/s41664-023-00267-x]
4. Weiwei Zhang, Leyu Dai, Tao Sun, Chuanxiang Qin, Jianjun Wang, Jun Sun, Lixing Dai. (2023) A transparent, self-adhesive and fully recyclable conductive PVA based hydrogel for wearable strain sensor. POLYMER, 283 (126281). [10.1016/j.polymer.2023.126281]
5. Xiang-Yu Wang, Ming-Wei Zhao, Xu-Hao Wang, Peng Liu, Meng-Yao Fan, Teng Li, Zhen-Feng Ma, Ying-Jie Dai, Cai-Li Dai. (2023) Intermolecular interactions induced property improvement for clean fracturing fluid by deep eutectic solvents. Petroleum Science, [10.1016/j.petsci.2023.08.013]
6. Linsheng Wang, Yulou Cui, Jiangtao Li, Zhen Song, Hongye Cheng, Zhiwen Qi. (2023) Toward high-performance associative extraction by forming deep eutectic solvent: A component pairing and mechanism study. CHEMICAL ENGINEERING SCIENCE, 272 (118602). [10.1016/j.ces.2023.118602]
7. Zhong Yuan, Zhang Jiangwei, Li Tingting, Xu Wenwu, Yao Qiaofeng, Lu Min, Bai Xue, Wu Zhennan, Xie Jianping, Zhang Yu. (2023) Suppression of kernel vibrations by layer-by-layer ligand engineering boosts photoluminescence efficiency of gold nanoclusters. Nature Communications, 14 (1): (1-12). [PMID:36746958] [10.1038/s41467-023-36387-2]
8. Mengyuan Jin, Sheng Cheng, Zhuo Yang, Yutong Luo, Yanhui Guo. (2023) A novel high-voltage solid electrolyte of Na3B24H23 for 4 V all-solid-state sodium battery. CHEMICAL ENGINEERING JOURNAL, 455 (140904). [10.1016/j.cej.2022.140904]
9. Jianhua Song, Lin Xu, Xiaoping Wang, Chonghao Chen, Weichong Wang, Haoyu Long, Muhammad Asif Nawaz, Dianhua Liu. (2023) Tailored acidic deep eutectic solvents: A multifunctional co-catalyst mediating homogeneous catalysis and heterogeneous separation of ethylene methoxycarbonylation. FUEL, 333 (126562). [10.1016/j.fuel.2022.126562]
10. Wei-Wei Yan, Xian-Yong Wei, Jun Li, Meng-Xiao Wang, Hong-Cun Bai, Zhi-Min Zong. (2022) Priority Separation of Phenols with Deep Eutectic Solvents from an Acetonitrile-Extractable Portion of a Shale Oil: Experimental and Computational. ENERGY & FUELS, 36 (11): (5657–5665). [10.1021/acs.energyfuels.2c00403]
11. Mei Jiang, Lin Zhu, Qian Zhao, Guangyuan Chen, Zeru Wang, Jingjing Zhang, Ling Zhang, Jiehong Lei, Tao Duan. (2022) Novel synthesis of NaY-NH4F-Bi2S3 composite for enhancing iodine capture. CHEMICAL ENGINEERING JOURNAL, 443 (136477). [10.1016/j.cej.2022.136477]
12. Yang He, Lihua Zhou, Shaohua Gou, Xiaolin Qian, Zhihao Tian, Junwen Chen, Jie Liao, Jing Huo, Guangjun Gou. (2022) Imidazolium Gemini ionic liquids for regulating facilely the swelling and dispersion of montmorillonite in water. APPLIED CLAY SCIENCE, 219 (106457). [10.1016/j.clay.2022.106457]
13. Xinquan Liang, Yuan Zhu, Benkun Qi, Shiqian Li, Jianquan Luo, Yinhua Wan. (2021) Structure-property-performance relationships of lactic acid-based deep eutectic solvents with different hydrogen bond acceptors for corn stover pretreatment. BIORESOURCE TECHNOLOGY, 336 (125312). [PMID:34044243] [10.1016/j.biortech.2021.125312]
14. Zeping Wang, Dingli Xie, Feng Zhang, Jiabing Yu, Xianping Chen, Ching Ping Wong. (2020) Controlling information duration on rewritable luminescent paper based on hybrid antimony (III) chloride/small-molecule absorbates. Science Advances, 6 (48): [PMID:33239292] [10.1126/sciadv.abc2181]
15. Yaqing Wang, Wenjun Chen, Qi Zhao, Guizhen Jin, Zhimin Xue, Yingxiong Wang, Tiancheng Mu. (2020) Ionicity of deep eutectic solvents by Walden plot and pulsed field gradient nuclear magnetic resonance (PFG-NMR). PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 22 (44): (25760-25768). [PMID:33147302] [10.1039/D0CP01431A]
16. Zifei Yan, Jian Deng, Yuchao Chen, Guangsheng Luo. (2020) Preparation of 2,3-Epoxypropyl Neodecanoate: Process Optimization and Mechanism Discussion. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 59 (43): (19168–19176). [10.1021/acs.iecr.0c02906]
17. Qi Zhang, Siru Ren, Song Xue, Ang Li, Siyao Liu, Xiaodong Sun. (2021) Tetraalkylammonium-l-tartrate ionic liquids as sole chiral selectors in capillary electrophoresis. SEPARATION AND PURIFICATION TECHNOLOGY, 256 (117842). [10.1016/j.seppur.2020.117842]
18. Xuejiang Cheng, Xin Wang, Guangming Chen. (2018) A convenient and highly tunable way to n-type carbon nanotube thermoelectric composite film using common alkylammonium cationic surfactant. Journal of Materials Chemistry A, 6 (39): (19030-19037). [10.1039/C8TA07746K]
19. Youan Ji, Yucui Hou, Shuhang Ren, Muge Niu, Congfei Yao, Weize Wu. (2018) Efficient extraction of indole from wash oil by quaternary ammonium salts via forming deep eutectic solvents. FUEL, 215 (330). [10.1016/j.fuel.2017.10.057]
20. Yucui Hou, Jie Kong, Yuehong Ren, Shuhang Ren, Weize Wu. (2017) Mass transfer dynamics in the separation of phenol from model oil with quaternary ammonium salts via forming deep eutectic solvents. SEPARATION AND PURIFICATION TECHNOLOGY, 174 (554). [10.1016/j.seppur.2016.10.038]
21. Xiao Huang, Yaofang Xuan, Lisiqi Xie, Bin Su. (2016) Unraveling the Phase-Transfer Catalysis Mechanism of Oxygen Reduction Catalyzed by Iron(III) meso-tetra-(4-N-Methyl-pyridyl) Porphine at the Liquid/Liquid Interface. ChemElectroChem, 3 (11): (1781-1786). [10.1002/celc.201600480]
22. Youan Ji, Yucui Hou, Shuhang Ren, Congfei Yao, Weize Wu. (2016) Phase equilibria of high pressure CO2 and deep eutectic solvents formed by quaternary ammonium salts and phenol. FLUID PHASE EQUILIBRIA, 429 (14). [10.1016/j.fluid.2016.08.020]
23. Xiao Huang, Lisiqi Xie, Xingyu Lin, Bin Su. (2016) Permselective Ion Transport Across the Nanoscopic Liquid/Liquid Interface Array. ANALYTICAL CHEMISTRY, 88 (12): (6563–6569). [PMID:27240714] [10.1021/acs.analchem.6b01383]
24. Yaofang Xuan, Xiao Huang, Bin Su. (2015) Biomimetic Oxygen Reduction Reaction Catalyzed by Microperoxidase-11 at Liquid/Liquid Interfaces. Journal of Physical Chemistry C, 119 (21): (11685–11693). [10.1021/acs.jpcc.5b02131]
25. Hua Tan, Wenxia Liu, Dehai Yu, Haidong Li, Martin A. Hubbe, Bei Gong, Wei Zhang, Huili Wang, Guodong Li. (2014) ASA-in-water emulsions stabilized by laponite nanoparticles modified with tetramethylammonium chloride. CHEMICAL ENGINEERING SCIENCE, 116 (682). [10.1016/j.ces.2014.06.005]

溶液计算器

摩尔浓度计算器

计算溶液所需的质量、体积或浓度。

质量

=

浓度

x

体积

x

分子量

g/mol

稀释计算器

计算配制储备溶液所需的稀释度。

浓度1（C1）

x

体积 1 (V1)

=

浓度 2 (C2)

x

体积 2 (V2)

复溶计算器

复溶计算器允许您快速计算试剂的体积，以复溶小瓶。只需输入试剂的质量和目标浓度，计算器将确定其余部分。

体积（添加到小瓶中）

=

质量（小瓶）

÷

所需的复溶浓度

货号 (SKU)	包装规格	是否现货	价格	数量
T139946-50g	50g	现货
T139946-250g	250g	现货

四甲基氯化铵

库存信息

库存信息

基本描述

关联靶点（人）

关联靶点（其它种属）

作用机制

名称和识别符

化学和物理性质

安全和危险性（GHS）

质量标准

质检证书（CoA,COO,BSE/TSE 和分析图谱)

此产品的引用文献

参考文献

溶液计算器

摩尔浓度计算器

稀释计算器

复溶计算器