共查询到19条相似文献,搜索用时 78 毫秒
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利用Langmuir-Blodgett(LB)膜技术能够使薄膜中聚合物分子链获得高度有序的排列与组装,并使沉积后的膜具备可控的特殊结构以及不同寻常的物理化学性质.高分子LB膜可用于制造非线性光学材料、光电子器件、传感器单元、电极修饰膜,也可作为研究催化反应、电子转移、仿生模拟的理想模型.本文评述了芳杂环类合成高分子(聚酰亚胺、聚噻吩、聚乙烯基咔唑和聚苯胺)与几种天然高分子(木质素、纤维素、壳聚糖和蛋白质)的LB膜最近的研究进展,并详细讨论了高分子LB膜的制备、结构与表征,指出了这两类高分子LB膜的研究重点,并对该两类高分子LB膜潜在的应用进行了展望. 相似文献
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高分子合金分离膜材料及结构研究进展 总被引:2,自引:0,他引:2
膜材料液相共混制备高分子合金分离膜不但可以调节膜材料与被分离物的亲和性,也在一定程度上改变了膜的结构。本文介绍高分子材料浓相共混对膜材料的亲水性、耐污染性及其它理化性能的影响和对膜结构的调节作用,同时指出高分子材料间的相容性是影响合金膜结构的重要因素。 相似文献
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本文结合近年来导电高分子的电化学阻抗谱(EIS)的研究进展,综述了几个EIS理论模型在导电高分子膜研究中的应用和发展。 相似文献
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进行了两种环境敏感高分子在相分离免疫分析嗜水气单胞菌外膜蛋白(outer membrane protein, OMP)中的比较研究. 首先合成温度敏感高分子聚N-异丙基丙烯酰胺和pH敏感高分子聚(N-异丙基丙烯酰胺-甲基丙烯酸), 分别以N-羟基琥珀酰亚胺丙烯酸酯(NAS)和碳二亚胺(EDCI)作为偶联剂与抗OMP抗体(Ab)偶联形成抗体复合物(Ab-polymer), 在竞争型免疫测定中, OMP标准溶液与异硫氰酸荧光素标记OMP在均相条件下竞争性地与Ab-polymer反应, 调节外界环境分离出高分子免疫复合物沉淀, 重新溶解后荧光法定量, 两种体系的OMP浓度均在400~3000 ng/mL范围内与荧光强度呈良好线性关系, 检出限分别为84.7和39.6 ng/mL. pH敏感高分子相比于温度敏感高分子具有以下优点: 可以在37 ℃的生理温度进行免疫反应, 进一步提高了免疫反应的速度和效率; 可利用高分子本身的活性基团进行Ab的固定, 固定化效率、固定Ab的免疫反应活性较之NAS偶联法得到了提高; 有更高的检测灵敏度. 因此, pH敏感高分子更适合于作为相分离免疫分析的载体. 相似文献
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Zwitterionic polymers are important in a wide range of industrial, biological and medical fields. Their chemical structures include an equal amount of anion and cation groups, and such structures give rise to many unique functionalities, such as temperature response, anti‐polyelectrolyte effect, and strong hydration properties. In this review, we focus on the structures and applications of functional zwitterionic polymers on surfaces. We review three areas of applications according to the architecture of the polymeric systems: surface coating, complex solutions, and hydrogel. We review the simulation and theory work and highlight some outlooks for further development. 相似文献
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功能性PolyNIP AAm系高聚物 总被引:7,自引:2,他引:5
本文总结了聚N-异丙基丙烯酰胺系温度敏感性高聚物研究的最新进展。对线型,水凝胶及基材接枝聚合物的制备方法,性质及应用研究几个方面进行了较为全面的详述。 相似文献
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Multicomponent reactions (MCRs) have been used to prepare polymers with appealing functions. The Biginelli reaction, one of the oldest and most famous MCRs, has sparked new scientific discoveries in polymer chemistry since 2013. Recent years have seen the Biginelli reaction stepping further from simple coupling tools; for example, the functions of the Biginelli product 3,4-dihydropyrimidin-2(1H)-(thi)ones (DHPM(T)) have been gradually exploited to develop new functional polymers. In this mini-review, we mainly summarize the recent progress of using the Biginelli reaction to identify polymers for biomedical applications. These polymers have been documented as antioxidants, anticancer agents, and bio-imaging probes. Moreover, we also provide a brief introduction to some emerging applications of the Biginelli reaction in materials and polymer science. Finally, we present our perspectives for the further development of the Biginelli reaction in polymer chemistry. 相似文献
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