聚合色素的研究 XI.蒽醌型聚酯色素的合成与可加工性

用熔融缩聚法合成蒽醌型聚酯色素，研究了色素用量、反应温度和反应时间等对反应的影响，对用所合成聚合色素着色的聚酯的可加工性能作了初步的研究。     

聚合色素的研究：Ⅺ.蒽醌型聚酯色素的合成与可加工性

用熔融缩聚法合成蒽醌型聚酯色素，研究了色素用量，反应温度和反应时间等对反应的影响，对用所合成聚合色素着色的聚酯的可加工性能作了初步的研究。     

桑色素分子印迹传感器的制备与应用

以邻氨基酚( o-AP)为功能单体,桑色素为模板分子,基于分子间的相互作用力,在金电极表面电聚合制备具有特异性识别孔穴的桑色素分子印迹传感器膜。采用循环伏安法( CV)、差分脉冲伏安法( DPV)等研究了分子印迹膜的性能和分子印迹效应。探索了聚合膜配比及聚合扫描圈数对传感器性能的影响,优化了洗脱时间和印迹时间。比较了此传感器对其结构相似物的选择性响应,发现其对桑色素检测具有良好的选择性。在最佳实验条件下,此传感器对桑色素浓度定量测定范围为0.05~1.70μmol/L,线性方程为I(μA)=1.0800lgc(mol/L)+9.3599, R=0.9934,检出限为0.01μmol/L。用此传感器测定黑茶样品中桑色素的含量,加标回收率为104.0%~108.0%。     

聚合色素的研究：Ⅳ.偶氮型聚合色素单体的溶剂效应

研究了六种可聚合色 素单体在１３种不同溶剂中的溶剂应，结果表明，溶质的最大吸不仅与溶剂的反射率有关，而且与溶剂的介电常数有关。     

聚合色素的研究：Ⅸ.侧链悬挂偶氮型染料的聚合膦腈酸多氟烷基 …

首次将偶氮染料和聚合膦腈酸多氟烷基取代酯相结合，合成了一类具有阻燃、疏水憎油等特殊的功能聚合物。研究了合成色素的润湿性和热性能，结果表明：所合成的色素具有期望的应用特性。此外，对合成反应的机理和聚合色素的红外光谱特性也进行了初步的讨论。     

聚合色素的研究Ⅸ.侧链悬挂偶氮型染料的聚合膦腈酸多氟烷基酯的合成和性能

首次将偶氮染料和聚合膦腈酸多氟烷基取代酯相结合，合成了一类具有阻燃、疏水憎油等特性的功能聚合物。研究了合成色素的润湿性和热性能，结果表明：所合成的色素具有期望的应用特性。此外，对合成反应的机理和聚合色素的红外光谱特性也进行了初步的讨论。     

原子力显微镜对细胞色素C分子结构的形态研究

用原子力显微镜(AFM)对不同浓度下细胞色素C的分子形态,以及加入蛋白质降聚和变性剂脲后的形态变化进行了考察。实验结果显示,在50μmol/L的低浓度溶液中细胞色素C分子主要以直径为3nm的类球形单体形式存在。浓度增大,细胞色素C分子发生聚集,且随着浓度的进一步增大,细胞色素C分子倾向于形成更大的聚集体。浓度为200μmol/L时,聚集体分子间相互缠绕,形成链状结构。浓度低于0.8mol/L的脲的加入基本不影响细胞色素C分子的形态。加入较高浓度的脲,细胞色素C聚集体的聚集数降低,聚集体分子间没有明显的链状结构。     

超分子聚合机理

与共价键聚合物由单体(M1)通过共价键连接不同,超分子聚合物是由单体(M2)通过非共价键连接而成的长链大分子。聚合包括分子聚合和超分子聚合。超分子聚合描述M2通过非共价键自组装形成超分子聚合物的过程,涉及氢键、π-π堆砌型和立体匹配等驱动力以及分子识别、协同性等特征,与M1通过共价键形成聚合物的过程(分子聚合)不同。为了理解超分子聚合物链结构形成机理,本文分析和讨论超分子聚合的三个主要机理:(1)线性链生长;(2)螺旋链生长;(3)拓扑链生长。     

萘酰亚胺类共聚色素的合成

以６－溴－１Ｈ，３Ｈ－萘并［１，８－ｃｄ］吡喃－１，３－二酮为原料，经亚胺化、Ｕｌｍａｍｎ缩合后与丙烯酰氯酯化得到具有荧光的可聚合单体６－（Ｎ－丙烯酰氧乙基）氨基－２－（２ ’，４ ’－Ｎ，Ｎ－二甲基）苯基－１Ｈ－苯并［ｄｅ］异喹啉－１，３（２Ｈ）－二酮，它与甲基丙烯酸甲酯经自由基共聚得到具有强烈荧光的聚合色素。     

氢键对N-乙酸乙酯甲基丙烯酰胺聚合的影响

<正> 分子间形成氢键对低分子化合物及高分子化合物物理性质的影响研究得比较多,对低分子有机化合物化学性质的影响研究也进行了大量工作。于宝善等研究表明单体分子间形成氢键对单体的自由基聚合能力是有影响的。 上述研究都是在芳香族酰胺及脂肪族酰胺类单体的液相本体聚合或熔融态的本体聚     

Polymeric Catalysts

The present-day position in the field of polymeric catalysts is outlined. The following selected groups of polymeric catalysts are discussed: synthetic hydrolases, immobilized enzymes, phase-transfer catalysts, nucleophilically active bases, polymers with conjugated π-systems, photosensitizers, polymers as carriers for catalytically active metals or ions, and immobilized homogeneous catalysts. Polymeric catalysts have the following valuable properties: insoluble polymeric catalysts are readily separable from reaction solutions and can often be re-used without loss of activity; a hydrophobic matrix protects the organometallic active center from deactivation by oxygen and water; by fixation of finely divided metals on an ion exchanger, multistage reactions may be effected successively in one reactor. Polymeric carriers may influence the catalytic properties; for example, in the case of immobilized enzymes on polyionic carriers the pH of the activity maximum may be shifted.     

Polymeric electrochromics

Conducting polymers are excellent candidates for applications in displays, mirrors, windows, light-emitting diodes, photovoltaics, near-infrared devices and electrochromic devices. From these potential applications, in this article, we will focus on the electrochromic polymers and devices. Although several objective studies have been conducted in the last decade, bringing to light many advantages over other types of electrochromics, polymeric electrochromics have not yet received the industrial attention that they deserve. One of the most important and dazzling advantages of polymers over the other types of electrochromics is the ease of modification of a polymer's backbone, that changes almost the entire properties of the material and switches many disadvantages into advantages. Our recent completion of the deficient third leg of additive primary colour space was a very good example of tailoring the polymer backbone. This discovery could be considered as one of the milestones of commercialization of polymeric electrochromics. In this article, we will also discuss the completion of the additive primary colours, red, green and blue (RGB), in polymeric electrochromics and their ways of commercialization.     

Polymeric Metallocarbenes

Three types of polymeric metallocarbenes were synthesized: heterocarbene, diarylcarbene, and alkylidene complexes. They were thermally more stable than their low molecular weight analogs. They exhibited ¹³C-NMR signals for the carbene carbons at very low magnetic field. They were characterized by typical metallocarbene reactions, such as nucleophilic substitution and oxidation, as well as cyclopropanation of unsaturated carboxylates. Thus, metallocarbenes, as an important category of organometallic compounds or intermediates, have gained entry to polymer chemistry.     

高分子固体电解质

本文叙述了高分子固体电解质的离子传导机理、特点及国内外近年来的研究进展和应用前景。     

高分子LB膜

概述了高分子Langmuir-Blogett膜,并依其成膜方式分别介绍了可聚合LB膜、聚合物的LB膜及其它几种LB膜。     

具有自修复能力的聚合物材料

各项性能已经达到工程材料指标要求的聚合物材料，在使用过程中不可避免地会产生裂纹，进而在使用过程中包藏着隐患，直至丧失使用价值。裂纹的早期修复，特别是自修复是一个现实而重要的问题。本文介绍了两类修复机制，即共价键与非共价键愈合，重点分析了近年来按共价键机理愈合、具有自修复能力的聚合物材料的研究成果、优缺点及发展前景。     

高分子效应

用许多杰出的实例,从高分子骨架的机械支架作用、邻基效应、协同效应、模板聚合等诸方面探论了高分子效应。     

Polymeric Electron Carriers

Polymers containing 1,4-dihydronicotinamide (P-NAH) alloxan (P-A), and viologen (P-V²⁺) moieties were synthesized and characterized. P-NAH reduced various organic substances such as lipoic acid, alloxan, and viologens and also immobilized quinone mediated by alloxan. P-A was reduced to the polymer-bearing alloxan radical and the dialuric acid structure without crosslinks by one- and two-electron reduction, respectively, and P-A also mediated the redox reaction occurring between aqueous and organic (water-immiscible) layers. P-V²⁺ was converted to the stable viologen radical reversibly by one-electron reduction. Electric potentials and currents on photo-reduction of P-V²⁺ and catalytic behavior of P-V²⁺ in the reduction of carbonyl compounds were examined.     

自修复高分子材料

高分子材料制造和使用过程中,经常由于内部的微裂纹和局部损伤,而导致性能下降,影响使用寿命。自修复高分子材料模仿生物体损伤愈合的原理,自行发现裂纹并通过一定机理自行愈合,是一种有着广泛应用需求的高分子智能材料,包括含修复剂型和不含修复剂型两类。它的特点在于自动化、精准化。本文旨在结合近年来最新的研究成果,介绍并归纳多种典型的自修复体系,总结各种优化手段,并针对已发展的自修复材料存在的局限性,对其研究前景进行合理的展望。     

Polymeric membrane pervaporation

Pervaporation is an efficient membrane process for liquid separation. The past decades had witnessed substantial progress and exciting breakthroughs in both the fundamental and application aspect of pervaporation. This review provided an analytical overview on the potential of pervaporation for separating liquid mixtures in terms of the solubility parameter and the kinetic parameter of solvents. Focus of the review was given to the fundamental understanding of the membrane. Research progress, challenges and opportunities, and the prospect of pervaporation were also discussed. The thermodynamic approach of pervaporation, featuring emphasizing membrane/species interactions, though gained great successes in the past decades, is now facing its toughest challenge in the org–org separation. A kinetic era of pervaporation, featuring emphasizing diffusion selectivity, as well as the synergy between the selective diffusion and sorption, is in the making, and this approach will eventually find solutions to the challenging org–org separation.