Development of temperature-responsive polymeric gels with physical crosslinking due to intermolecular 𝜋–𝜋 interactions
Rishabh A Shah, Tyler Runge, Thomas W Ostertag, Shuo Tang, Thomas D Dziubla, J Zach Hilt
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Abstract
Poly(N -isopropylacrylamide) was polymerized with comonomers containing a biphenyl moiety to create a unique thermoresponsive physically crosslinked system due to the presence of π –π interactions between the biphenyl moieties. The biphenyl monomers used were 2-phenylphenol monoacrylate (2PPMA) and 4-phenylphenol monoacrylate (4PPMA). These monomers were utilized to synthesize a set of polymers with biphenyl monomer (2PPMA/4PPMA) content from 2.5 to 7.5 mol% and with initiator concentrations of 0.1 and 1.0 wt%. The resulting polymers were characterized using various techniques, such as gel permeation chromatography (GPC), swelling studies and mechanical testing. A decrease in the average molecular weight of the polymers due to the increase in the concentration of initiator was confirmed from GPC results. Swelling studies confirmed the expected temperature-dependent swelling properties and explored the impact of the biphenyl comonomers. These studies indicated that with an increase in biphenyl comonomer content, the physical crosslinking increases which leads to a decrease in the swelling ratio. The results from the mechanical tests also indicate the effect of the concentration of biphenyl comonomers. These physically crosslinked polymeric systems with their unique properties have potential applications spanning environmental remediation/sensing, biomedicine, etc. © 2021 Society of Industrial Chemistry.
由于分子间相互作用而产生物理交联的温度响应聚合物凝胶的研制
聚n -异丙基丙烯酰胺(n -异丙基丙烯酰胺)与含有联苯基团的共聚单体聚合,由于联苯基团之间存在π -π相互作用,形成了一种独特的热响应性物理交联体系。所使用的联苯单体是2-苯基苯酚单丙烯酸酯(2PPMA)和4-苯基苯酚单丙烯酸酯(4PPMA)。利用这些单体合成了一组联苯单体(2PPMA/4PPMA)含量为2.5 ~ 7.5 mol%,引发剂浓度为0.1和1.0 wt%的聚合物。所得到的聚合物使用各种技术进行表征,如凝胶渗透色谱(GPC)、膨胀研究和力学测试。GPC结果证实了引发剂浓度的增加导致聚合物平均分子量的降低。膨胀研究证实了预期的温度依赖性膨胀特性,并探索了联苯共聚体的影响。这些研究表明,随着联苯单体含量的增加,物理交联增加,导致膨胀率降低。力学试验结果也表明了联苯单体浓度的影响。这些物理交联聚合物体系具有独特的性能,在环境修复/传感、生物医学等领域具有潜在的应用前景。©2021工业化学学会。
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