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4-丙烯酰吗啉

30篇引用文献 COA COA
    级别和纯度:
  • ≥98%(GC)
  • 含稳定剂MEHQ
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货号 (SKU) 包装规格 是否现货 价格 数量
A151729-5ml
 5ml 现货 Stock Image
A151729-25ml
 25ml 现货 Stock Image
A151729-100ml
 100ml 现货 Stock Image
A151729-500ml
 500ml 现货 Stock Image
A151729-2.5L
 2.5L 现货 Stock Image
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六元杂环化合物 (1701) 吗啉类 (213)
main product photo

基本描述

别名 4-甲氧基苯酚稳定剂 | 1-吗啉代丙-2-烯-1-酮 | 4-(1-氧代-2-丙烯基)吗啉 | 1-(吗啉-4-基)丙烯酮 | 4-丙烯酰基吗啉
英文别名 NCGC00256280-01 | NSC162221 | NSC-162221 | acryloylmorpholine | K0Y58P61JA | 4-Acryloylmorpholine (stabilized with MEHQ) | 4-Acryloylmorpholine, 97%, contains 1,000 ppm monomethyl ether hydroquinone as inhibitor | Tox21_301658 | ACRYLOYL MORPHOLINE | N-Ac
规格或纯度 ≥98%(GC), 含稳定剂MEHQ
英文名称 4-Acryloylmorpholine
储存温度 2-8°C储存
运输条件 冰袋运输
产品介绍

4-丙烯酰吗啉是一种丙烯酸酯单体,在聚合物工业中广泛用作交联剂。它用于 形成三维聚合物网络,增强材料的机械强度、 稳定性和耐久性。丙烯酰吗啉中的吗啉部分 使分子具有亲水性,促进 其在粘合剂、生物相容性涂层和药物输送系统领域 的应用。它还用作反应性单体,合成用于药物输送的水凝胶、用于3D生物打印和显示设备的光固化材料和显示装置。 

用途

4-丙烯酰吗啉可在以下反应过程中用作单体:
RAFT聚合法合成多嵌段 共聚物。 这些功能性嵌段共聚物在医学、能源和纳米技术领域都有应用。 
光聚合和交联法制备 有机凝胶电极框架。聚合和交联催化剂。这可用于制造具有出色透明度、 可拉伸性和界面粘附性的摩擦纳米发电机。 
用于打印热塑性3D组织支架。ACMO可溶于水,粘度极低,且具有表面氧阻聚作用,在高速露天打印过程中可促进液体快速流动。

4-Acryloylmorpholine is an acrylate monomer widely used as a crosslinking agent in the polymer industry. It is used to form three-dimensional polymer networks to enhance the mechanical strength, stability, and durability of materials. The morpholine moiety in acryloylmorpholine imparts hydrophilicity to the molecule facilitating its applications in the field of adhesives, biocompatible coatings, and drug delivery systems. It is also used as a reactive monomer to synthesize hydrogels for drug delivery, photocurable materials for 3D bioprinting and display devices. 

Purpose

4-Acryloylmorpholine can be used as a monomer:
To synthesize multiblock copolymers via RAFT polymerization. These functional block copolymers find application in the fields of medicine, energy, and nanotechnology.
To prepare organogel electrode frame via photopolymerization and cross-linking. This can be used to fabricate triboelectric nanogenerators with excellent transparency, stretchability, and interface adhesion.
For printing thermoplastic 3D tissue scaffolds. ACMO′s water solubility,and remarkably low viscosity, combined with surface oxygen inhibition, promoteswift liquid flow during high-speed open-air printing.

纯度 ≥98%(GC)

名称和识别符

PubChem SID 488187143
分子类型 小分子
IIUPAC Name 1-morpholin-4-ylprop-2-en-1-one
INCHI 1S/C7H11NO2/c1-2-7(9)8-3-5-10-6-4-8/h2H,1,3-6H2
InChi Key XLPJNCYCZORXHG-UHFFFAOYSA-N
Smiles C=CC(=O)N1CCOCC1
Isomeric SMILES C=CC(=O)N1CCOCC1
分子量 141.17
Reaxy-Rn 119302
Reaxys-RN link address https://www.reaxys.com/reaxys/secured/hopinto.do?context=S&query=IDE.XRN=119302&ln=

化学和物理性质

溶解性 Soluble in chloroform, toluene, Acetone, alcohol, benzene
密度 1.122
敏感性 对光敏感
折光率 1.512
闪点(℉) 260°F
闪点(℃) 127°C
沸点 165°C/16mmHg
熔点 -35 °C
分子量 141.170 g/mol
XLogP3 -0.100
氢键供体数Hydrogen Bond Donor Count 0
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 141.079 Da
单同位素质量Monoisotopic Mass 141.079 Da
拓扑极表面积Topological Polar Surface Area 29.500 Ų
重原子数Heavy Atom Count 10
形式电荷Formal Charge 0
复杂度Complexity 139.000
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 GHS05,   GHS07,   GHS08
信号词 危险

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F2512114 分析证书 A151729
F2512133 分析证书 A151729
F2512134 分析证书 A151729
F2512135 分析证书 A151729
L2410396 分析证书 A151729
L2410251 分析证书 A151729
L2410263 分析证书 A151729
L2410397 分析证书 A151729
L2410262 分析证书 A151729
J2425350 分析证书 A151729
J2425355 分析证书 A151729
J2425357 分析证书 A151729
J2425358 分析证书 A151729
G2431071 分析证书 A151729
G2431070 分析证书 A151729
G2431072 分析证书 A151729
G2431073 分析证书 A151729
E2421482 分析证书 A151729
E2421404 分析证书 A151729
E2421477 分析证书 A151729
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K2303093 分析证书 A151729
K2303094 分析证书 A151729
K2303102 分析证书 A151729
K2303103 分析证书 A151729
C2426032 分析证书 A151729
G2308430 分析证书 A151729
G2308432 分析证书 A151729
G2308442 分析证书 A151729
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G2308469 分析证书 A151729
D2325312 分析证书 A151729
D2325313 分析证书 A151729
D2325316 分析证书 A151729
A1914062 分析证书 A151729
K2222323 分析证书 A151729
K2222324 分析证书 A151729
C2307720 分析证书 A151729
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3. Yujie Yang, Xin Xu, Zhiqiang Li, Xinle Yao, Dongqing Kang, Yaozhong Lu, Yanbin Wang, Yuxiong Guo, Xiaolong Wang.  (2023)  Synthesis and properties of vat photopolymerization 3D-printing benzoxazine.  MATERIALS LETTERS,  345  (134448).  [10.1016/j.matlet.2023.134448]
4. Qian Zhou, Tengjiao Wang, Kunpeng Li, Shanyu Zhang, Kun Wang, Weilin Hong, Rongjun Liu, Peng Li.  (2023)  Biofilm microenvironment-responsive polymeric CO releasing micelles for enhanced amikacin efficacy.  JOURNAL OF CONTROLLED RELEASE,  357  (561).  [PMID:37076015] [10.1016/j.jconrel.2023.04.025]
5. Baimei Dai, Peng Xu, Mingbiao Xu, Qisheng Jiang, Qinglin Liu, Siwei Wang.  (2023)  Synthesis and plugging effect of inverse emulsion polymerization microspheres (OPME) for oil-based drilling fluids.  Arabian Journal of Chemistry,  16  (104577).  [10.1016/j.arabjc.2023.104577]
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8. Shenglong Shi, Jinsheng Sun, Kaihe Lv, Qingzhi Wen, Yingrui Bai, Jintang Wang, Jiafeng Jin, Jingping Liu, Xianbin Huang, Jian Li.  (2022)  Preparation and evaluation of acryloyl morpholine modified emulsion fracturing fluid thickener with high temperature resistance and salt resistance.  JOURNAL OF APPLIED POLYMER SCIENCE,  140  (3): (e53338).  [10.1002/app.53338]
9. Shenglong Shi, Jinsheng Sun, Kaihe Lv, Jingping Liu, Yingrui Bai, Jintang Wang, Xianbin Huang, Jiafeng Jin, Jian Li.  (2022)  Comparative Studies on Thickeners as Hydraulic Fracturing Fluids: Suspension versus Powder.  Gels,  (11): (722).  [PMID:36354629] [10.3390/gels8110722]
10. Wenpeng Zhao, Yuan Li, Jian Hu, Xianqi Feng, Hao Zhang, Jun Xu, Shouke Yan.  (2023)  Mechanically robust, instant self-healing polymers towards elastic entropy driven artificial muscles.  CHEMICAL ENGINEERING JOURNAL,  454  (140100).  [10.1016/j.cej.2022.140100]
11. Feifan Sheng, Bo Zhang, Yihan Zhang, Yanyan Li, Renwei Cheng, Chuanhui Wei, Chuan Ning, Kai Dong, Zhong Lin Wang.  (2022)  Ultrastretchable Organogel/Silicone Fiber-Helical Sensors for Self-Powered Implantable Ligament Strain Monitoring.  ACS Nano,  16  (7): (10958–10967).  [PMID:35775629] [10.1021/acsnano.2c03365]
12. Wenpeng Zhao, Zixiang Zhang, Jian Hu, Xianqi Feng, Jun Xu, Yumin Wu, Shouke Yan.  (2022)  Robust and ultra-fast self-healing elastomers with hierarchically anisotropic structures and used for wearable sensors.  CHEMICAL ENGINEERING JOURNAL,  446  (137305).  [10.1016/j.cej.2022.137305]
13. Xu Jun, Zhang Zixiang, Nie YongJia, Liu Yanxia, Fan Yue, Zhao Wenpeng, Feng Xianqi.  (2022)  Dual physical cross-linked self-healing elastomer for the triple shape memory.  JOURNAL OF MATERIALS SCIENCE,  57  (24): (11430-11442).  [10.1007/s10853-022-07243-3]
14. Zhuo Sun, Yahui Lu, Qian Zhao, Jingjun Wu.  (2022)  A new stereolithographic 3D printing strategy for hydrogels with a large mechanical tunability and self-weldability.  Additive Manufacturing,  50  (102563).  [10.1016/j.addma.2021.102563]
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