基于原位自由基共聚技术的复合水凝胶制备及表征

Preparation and Characterization of Composite Hydrogel Based on In-Situ Radical Copolymerization Technology

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摘要以聚乙二醇与马来酸酐的双酯化产物(MAh-PEG-MAh)、丙烯酰胺(AM)为单体,N,N’-亚甲基双丙烯酰胺(BIS)或对二乙烯基苯(DVB)为交联剂,通过原位自由基共聚法合成了一种复合水凝胶。利用FT-IR、1H-NMR、SEM、TEM表征了凝胶结构和形态;利用XRD研究了凝胶的结晶性;研究了单体用量、分子链段长度、交联剂等因素对凝胶力学性能的影响。研究表明,柔性链段MAh-PEG-MAh以一定尺寸的聚集微区分散于PAM连续相,增强水凝胶的结晶性,且分散相与连续相之间有良好的作用力,当MAh-PEG1K-MAh与AM的物质的量比为1∶8,复合水凝胶的压缩强度达到18.2 MPa左右,力学性能最佳。 A kind of composite hydrogel was synthesized by in-situ radical copolymerization using esterified products of polyethylene glycol and maleic anhydride （MAh-PEG-MAh）, and acrylamide （AM） as monomers, N, N- methylenebis（acrylamide）（BIS） or 1,4-divinyl benzene （DVB）as cross-linker. The structure of resultant hydrogel was characterized by FT-IR, 1H-NMR, SEM, TEM and XRD. The influences of the amount of monomers, molecular chain length and cross-linking agent etc on the mechanical strength of composite were studied. Studies show that in the hydrogel prepared from heterogeneous polymerization system using DVB as crosslinker and AIBN as initiator, the flexible segment of MAh-PEG-MAh oggregates as micro-areas with certain size and disperses uniformly in the continuous phase of PAM, the crystallinity of hydrogel increases. Good interaction force between the dispersed phase and continuous phase enables the external forces to be consumed by viscous dissipation or large deformation. When the molar ratio of MAh-PEGIK-MAh to AM is 1 ： 8, the compressive strength of the prepared hydrogel reaches its maximum value about 18.2 MPa.

作者许一婷邓胡军宋存峰曾福泉何凯斌罗伟昂曾碧榕戴李宗

机构地区厦门大学化学化工学院厦门大学材料学院

出处《高分子材料科学与工程》 EI CAS CSCD 北大核心 2013年第3期128-132,共5页 Polymer Materials Science & Engineering

基金国家自然科学基金资助项目(50903066 51273164) 福建省自然科学基金资助项目(2012J01233)

关键词水凝胶丙烯酰胺聚乙二醇力学强度马来酸酐原位共聚 hydrogel acrylamide polyethylene glycol mechanical strength maleic anhydride in situcopolymerization

分类号 TQ316 [化学工程—高聚物工业]

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1Matthias B, Robert L, Rudolf Z, et al. Overcoming the PEG- addiction: Well-defined alternatives to PEG from structure property relationships to better defined therapeutics [J ]. Polym. Chem., 2011, 2(9): 1900-1918.
2Caulfield M J, Qiao G G, Solomon D H. Some aspects of the properties and degradation of polyacrylamides [ J ]. Chem. Rev. 2002, 102(9): 3067-3083.
3Nandi N, Bhattacharyya K, Bagehi B. Dielectric relaxation and solvation dynamics of water in complex chemical and biological Systems[J]. Chem. Rev. 2000, 100(6): 2013-2045.
4Gong J P, Katsuyama Y, Kurokawa T, et al. Double network hydrogels with extremely high mechanical strength [ J ]. Adv. Mater. ,2003, 15(14): 1155-1158.
5Hooper H H, Baker J P, Blanch H W, et al. Swelling equilibria for positively ionized polyacrylamide hydrogels [ J ]. Macromolecules, 1990, 23(4): 1096-1104.
6Yang H N, Takayuki K, Yoshinofi K, et al. Structural characteristics of double network gels with extremely high mechanical strength[J]. Macromolecules, 2004, 37 (14): 5370-5374.
7Hiroyuki T, Mei H, Yang H N, et al. Effect of polymer .entanglement on the toughening of double-network of hydrogels [J]. J. Phys. Chem. B, 2005, 109(34): 16304-16309.
8Na Y H, Tanaka Y, Kawauchi Y, et al. Necking phenomenon of double-network gels [J ]. Macromolecules, 2006, 39 (14) : 4641- 4645.

1胡友良,陈商涛.烯烃的共聚合反应及聚烯烃改性:Ⅰ.烯烃与极性单体的共聚合[J].石化技术与应用,2004,22(1):1-3. 被引量：3
2钱伯章.碳纤维核心技术突破国产化瓶颈[J].合成纤维工业,2010,33(3):35-35.
3胡友良,马志,吕英莹.LLDPE的发展现状和技术创新[J].石化技术与应用,2003,21(1):1-4. 被引量：9
4宁英男,姜涛,张丽.气相法聚乙烯工艺技术及其催化剂进展[J].石化技术与应用,2008,26(5):480-485. 被引量：22
5张启兴,杨海滨,周勰,王海华.SiCl_4、PPh_3促进的TiCl_4/Ni(acac)_2复合催化剂的乙烯聚合研究[J].石油化工,2001,30(6):448-452.
6胡友良,张晓帆.烯烃共聚合反应及聚烯烃改性:Ⅱ.烯烃配位活性聚合和功能化[J].石化技术与应用,2004,22(2):77-81. 被引量：2
7聚甲醛的技术进展与市场分析（下）[J].橡塑机械时代,2009,21(12):14-16. 被引量：1
8简讯[J].塑料科技,2004,32(2):10-10.
9杜威,姜涛,宁英男.聚丙烯合金技术的研究进展[J].石油化工,2008,37(2):191-197. 被引量：12
10一种原位共聚制备线性低密度聚乙烯的催化剂体系[J].国内外石油化工快报,2007,37(6):32-32.

高分子材料科学与工程

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基于原位自由基共聚技术的复合水凝胶制备及表征

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