梯形聚硅氧烷的研究进展

梯形聚硅氧烷(R-LPS)因其独特的双链或多重链结构而具有较单链聚硅氧烷更高的耐热、耐氧化、耐辐射性以及良好的生物稳定性。自从上世纪60年代R-LPS首次被报道以来,一直受到广泛的关注。随着人们对分子间弱相互作用认识的加深,对R-LPS的形成机理、制备方法和性能的研究,都有进一步的发展,并涉及超分子自组装、化学合成、纳米结构及性能表征等许多高分子科学的前沿问题。本文根据近五年来采用"超分子构筑调控逐步偶联和聚合"方法合成的新型双链、三重链及四重链梯形聚硅氧烷及其性能进行了综述,其中包括具有不同侧基的R-LPS的合成与表征。     

高规整梯形聚乙烯基倍半硅氧烷的合成

采用具有"同步增长,同步断撑和原位缩合"特性的超分子构筑调控逐步偶联和聚合方法,合成了高规整的反应性梯形聚乙烯基倍半硅氧烷Vi-LPSQ.该反应性乙烯基可进一步功能化,是制备功能高分子材料的重要前驱体.29Si-NMR是表征梯形聚合物规整性最有效的方法,Vi-LPSQ的重复结构单元共振吸收峰的化学位移δ=-21.6,且峰宽Δca.1,说明其规整性很高.它的XRD谱图上存在两个明显的衍射峰,分别对应于梯形的宽度(d1=0.74 nm)和厚度(d2=0.40 nm),这证实了Vi-LPSQ以典型的梯形结构存在.另外,Vi-LPSQ的玻璃化转变温度Tg高达191.3℃,表明Vi-LPSQ分子具有很高的刚性和规整性.     

反应性梯形聚氢基倍半硅氧烷合成方法的改进

对反应性梯形聚氢基倍半硅氧烷 (H T)的合成方法进行了改进 .首先利用硅羟基与硅氯基之间的脱氯化氢缩聚来代替以前采用的硅羟基间脱水缩聚反应 ,进一步提高了作为梯撑的对苯二胺之间氢键在聚合反应中的模板作用 .另外利用三甲基氯硅烷与对苯二胺梯撑的聚硅氧烷中间体的末端硅羟基进行封端反应 ,从而保证在脱除对苯二胺梯撑模板分子过程中避免进一步的无规缩合导致支化或交联 ,得到的反应性梯形聚氢基倍半硅氧烷 (H T)的规整性有所改善 .热分析结果表明与单链聚二甲基硅氧烷的Tg(- 12 3℃ )相比 ,其Tg 高达 117 0℃ ,证明这种梯形高分子具有刚性链结构 .尤其是2 9Si NMR谱中代表梯形主链上硅原子 (SiO3 2 )峰的基线宽度Δ =5 ,而采用硅羟基间脱水缩合方法得到聚合物的Δ =8～ 10 .表明该反应性梯形聚氢基倍半硅氧烷H T的规整性得到了明显的提高 .而且 ,该聚合物又是第一个可溶性、反应性、纯梯形主链无机高分子 ,它可以进一步通过硅 氢侧基接枝反应制备不同类型的梯形无机主链功能高分子 .     

5-氨基间苯二酸和1,10-邻菲咯啉镱配合物的合成、晶体结构及表征

<正>0引言近年来,利用弱的非共价作用力例如氢键、π-π堆积以及静电作用来组装结构新颖的超分子配位聚合物已成为配位化学和超分子化学的研究热点之一[1]。其中芳香羧酸的稀土超分子配位聚合物由于其优良的发光性能和在催化、分离和气体储存等方面展示了广阔的应用前景以及新颖的结构而倍     

光响应超分子聚合物

超分子聚合物是超分子化学、高分子化学和材料化学领域的研究热点.将光响应的功能基团以非共价作用构筑到超分子聚合物体系中,得到光响应型超分子聚合物,从而能够将超分子聚合物的独特性质与光化学反应的优势有效地结合起来,从而构筑新型的光功能材料.本文总结了近年来本课题组有关光响应超分子聚合物方面的研究工作:介绍了主链型的光响应超分子聚合物的光调控组装和解离,超分子聚合物和共价聚合物的光控可逆切换和光调控组装形貌;另外还举例介绍了具有自修复和室温磷光发射等功能的侧链型光响应超分子聚合物,并对刺激-响应的超分子聚合物领域的发展做了展望.     

梯形聚硅氧烷液晶的研究进展

摘 要 梯形聚硅氧烷液晶具有独特的稳定性、透明性及成膜性等优点,是一种性能优异的新型功能材料。本文综述了梯形聚硅氧烷液晶近年来的发展现状;介绍了梯形聚硅氧烷液晶的结构特点,根据液晶基元接枝到梯形高分子主链上的方式,将梯形聚硅氧烷液晶分为鱼骨形和划艇形两种;总结了挂接不同侧基的梯形聚硅氧烷的合成路线,包括梯形聚苯基倍半硅氧烷、梯形聚甲基倍半硅氧烷、梯形聚氢基倍半硅氧烷、梯形聚乙烯基倍半硅氧烷等;介绍了几种液晶基元不同的梯形聚硅氧烷液晶的合成;最后提出了几个梯形聚硅氧烷液晶研究工作面临的问题,并对梯形聚硅氧烷液晶的发展前景做出了展望。     

超分子和高分子自组装的动力学模拟研究

超分子和高分子的自组装是发展新型高性能材料的有力手段.通过自组装构筑多级有序结构,从而显著提高材料的力学、光学或电学性能,是化学和材料科学研究的前沿.然而精确调控自组装需要深入理解范德华、氢键、静电、主客体复合和π-π等相互作用以及动力学机理所扮演的角色.计算机模拟,尤其是分子动力学模拟,为研究自组装结构和演化过程提供了独一无二的手段.本文主要阐述超分子和高分子的多尺度模型和动力学模拟方法,讨论不同模拟方法的特点、适用范围和优势;进一步简述我们发展的定制模型和方法,以及同时提高模型精度和计算效率方面采取的策略.通过总结应用这些方法对超分子和高分子自组装开展的研究工作所取得的进展,为进一步发展自组装动力学模拟方法提供参考.     

梯形聚硅氧烷液晶的研究

梯形聚硅氧烷液晶具有独特的稳定性、透明性及成膜性等优点,是一种性能优异的新型功能材料。本文综述了梯形聚硅氧烷液晶近年来的发展现状。介绍了梯形聚硅氧烷液晶的结构特点,根据液晶基元接枝到梯形高分子主链上的方式,将梯形聚硅氧烷液晶分为鱼骨形和划艇形两种。总结了挂接不同侧基的梯形聚硅氧烷（包括梯形聚苯基倍半硅氧烷、梯形聚甲基倍半硅氧烷、梯形聚氢基倍半硅氧烷、梯形聚乙烯基倍半硅氧烷等）的合成路线。介绍了几种液晶基元不同的梯形聚硅氧烷液晶的合成方法。最后提出几个梯形聚硅氧烷液晶研究工作面临的问题,并对梯形聚硅氧烷液晶的发展前景作了展望。     

超分子拓扑高分子：合成、组装及功能

超分子拓扑高分子结合了非共价键的动态可逆特性和共价型拓扑高分子的结构特点,是一种具有广泛应用前景的高分子物种.本文从超分子拓扑高分子的合成、组装及功能等三个方面综述了该领域的最新研究进展.首先重点强调了利用直接或间接方法来构筑超支化、树枝状、星形、刷形、交联型和环形等超分子拓扑高分子的策略,其次从内部结构参数和外部环境响应两方面介绍了调控超分子自组装行为的主要方法,然后对其在生物医用材料、光电活性材料以及自修复材料等领域的潜在应用进行了较为全面的总结,最后指出了超分子拓扑高分子研究领域目前存在的关键问题和重要挑战.     

超分子聚合物制备新方法:超分子单体的共价聚合

超分子聚合物是超分子化学与高分子化学交叉的前沿研究领域,近年来受到了国内外研究学者的广泛关注.可控制备超分子聚合物对于研究超分子聚合物的结构与性能关系、设计合成特定功能的超分子聚合物具有重要的意义.本文将总结通过超分子单体的共价聚合反应以制备超分子聚合物的方法.不同于传统的制备超分子聚合物的方法,超分子单体的共价聚合方法将不易调控的非共价聚合转化为可控的共价聚合,为实现超分子聚合物的可控制备提供了新思路.     

界面超分子聚合

超分子聚合物诞生于高分子化学与超分子化学的交叉融合,一般是指单体间通过非共价键作用连接形成的聚合物,并在溶液或体相中表现出类似聚合物的性质。目前超分子聚合物一般通过均相溶液聚合制备得到,但溶液中的超分子聚合是一个自发的组装过程,具有浓度依赖性,组装过程不易可控。为解决此问题,研究人员可以将超分子聚合从均相溶液转移到界面,在界面上可控地制备超分子聚合物。通过界面聚合制备超分子聚合物具有一些独特的优势,如可以制备得到分子量更高的超分子聚合物,易于制备一些缺陷少、面积大、有序的二维超分子聚合物等。本文基于在液-液、气-液和固-液三种界面上制备超分子聚合物的一些代表性工作,介绍了界面超分子聚合方法和应用,并展望其未来发展。     

Polymers with advanced structural and supramolecular features synthesized through topochemical polymerization

Polymers are an integral part of our daily life. Hence, there are constant efforts towards synthesizing novel polymers with unique properties. As the composition and packing of polymer chains influence polymer''s properties, sophisticated control over the molecular and supramolecular structure of the polymer helps tailor its properties as desired. However, such precise control via conventional solution-state synthesis is challenging. Topochemical polymerization (TP), a solvent- and catalyst-free reaction that occurs under the confinement of a crystal lattice, offers profound control over the molecular structure and supramolecular architecture of a polymer and usually results in ordered polymers. In particular, single-crystal-to-single-crystal (SCSC) TP is advantageous as we can correlate the structure and packing of polymer chains with their properties. By designing molecules appended with suitable reactive moieties and utilizing the principles of supramolecular chemistry to align them in a reactive orientation, the synthesis of higher-dimensional polymers and divergent topologies has been achieved via TP. Though there are a few reviews on TP in the literature, an exclusive review showcasing the topochemical synthesis of polymers with advanced structural features is not available. In this perspective, we present selected examples of the topochemical synthesis of organic polymers with sophisticated structures like ladders, tubular polymers, alternating copolymers, polymer blends, and other interesting topologies. We also detail some strategies adopted for obtaining distinct polymers from the same monomer. Finally, we highlight the main challenges and prospects for developing advanced polymers via TP and inspire future directions in this area.

This perspective showcases the potential of topochemical polymerization as an effective tool for synthesizing polymers with advanced molecular and supramolecular structures.     

Routes to Hydrogen Bonding Chain‐End Functionalized Polymers

The contribution of supramolecular chemistry to polymer science opens new perspectives for the design of polymer materials exhibiting valuable properties and easier processability due to the dynamic nature of non‐covalent interactions. Hydrogen bonding polymers can be used as supramolecular units for yielding larger assemblies that possess attractive features, arising from the combination of polymer properties and the responsiveness of hydrogen bonds. The post‐polymerization modification of reactive end‐groups is the most common procedure for generating such polymers. Examples of polymerizations mediated by hydrogen bonding‐functionalized precursors have also recently been reported. This contribution reviews the current synthetic routes toward hydrogen bonding sticker chain‐end functionalized polymers.     

Water-soluble supramolecular polymers constructed by macrocycle-based host-guest interactions

Water soluble supramolecular polymers are especially important due to their superior biocompatibility and environmental adaptation, which determined they have wide applications in various areas, such as drug delivery, self-healing, shape memory. On the other hand, macrocyclic compounds are the most used building blocks in the preparation of supramolecular polymers. Macrocycle-based supramolecular polymers, which introduce the host-guest interaction in the system, endow these polymers with interesting and smart physicalchemical properties. In this review, we summarized recent studies about supramolecular polymers in aqueous solution based on macrocyclic compounds.     

超分子高分子化学进展

综述了超分子高分子化学近年来的进展,着重介绍固相聚合和毛杆高分子等方面的最新研究成果及应用展望,对超分子高分子化学的主要研究方法也作了扼要的介绍。     

Three-Strand Conducting Ladder Polymers: Two-Step Electropolymerization of Metallorotaxanes

Sequential polymerization of supramolecular metallorotaxane complexes results in three-stranded conducting ladder polymers. The internal polymer is "sandwiched" between the other two polymers to give molecular wires that are effectively insulated when the outer polymers are in their nonconducting state (shown schematically). The intermolecular conductivity can be mediated by the Cu(1+)/Cu(2+) redox couple.     

Halogen bonding in polymer science: towards new smart materials

The halogen bond is a special non-covalent interaction, which can represent a powerful tool in supramolecular chemistry. Although the halogen bond offers several advantages compared to the related hydrogen bond, it is currently still underrepresented in polymer science. The structural related hydrogen bonding assumes a leading position in polymer materials containing supramolecular interactions, clearly indicating the high potential of using halogen bonding for the design of polymeric materials. The current developments regarding halogen bonding containing polymers include self-assembly, photo-responsive materials, self-healing materials and others. These aspects are highlighted in the present perspective. Furthermore, a perspective on the future of this rising young research field is provided.

The incorporation of halogen bonding into polymer architectures is a new approach for the design of functional materials. This perspective emphasizes the current development in the field of halogen bonding featuring polymer materials.     

SYNTHESIS AND CHARACTERIZATION OF A NOVEL REACTIVE LADDER-LIKE POLYSILSESQUIOXANE WITH LATERAL BROMOPHENYL GROUPS

A novel soluble, reactive ladder-like polysilsesquioxane (L) with lateral bromophenyl groups was synthesized successfully by stepwise coupling polymerization (SCP) method including preaminolysis, hydrolysis and polycondensation steps. The monomer 3-trichlorosilylpropoxy-4-bromobenzene (M) was first prepared via hydrosilylation reaction catalyzed by dicyclopentadienylplatinum (Ⅱ) dichloride (Cp2PtCl2). The title polymer (L) was characterized by ^1H-NMR, ^29Si-NMR,FTIR, X-ray diffraction (XRD), DSC and vapor pressure osmometry (VPO). The experimental results indicate that the polymer (L) possesses a typical ladder-like structure.     

Asymmetrical supramolecular interactions as basis for complex responsive macromolecular architectures

Intrigued by natural responsive systems based on a combination of macromolecules and non-covalent interactions, polymer scientists have mimicked such systems by the formation of supramolecular polymers based on ionic interaction, hydrogen bonding and metal coordination. In recent years, the focus has shifted from rather simple non-directional and self-complementary interactions to the use of asymmetrical directional supramolecular interactions that allow the formation of complex responsive macromolecular architectures such as block copolymers, star-shaped polymers and graft copolymers. This feature article covers these recent developments on the use of asymmetrical supramolecular interactions in polymer science. Special attention is given to the formation of complex macromolecular architectures using directional supramolecular interactions. In addition, the responsiveness of the resulting macromolecular systems is discussed based on the assembly and/or disassembly that can be triggered by changes in external conditions.     

苯乙烯阴离子本体聚合引发剂缔合及其机理的研究

分别以正丁基锂和叔丁基锂为引发剂,采用自制管式流动反应装置,对较高温度下苯乙烯阴离子本体聚合动力学进行了研究.证实了正丁基锂主要以六元缔合结构形式引发聚合,并导致超分子团聚体的形成,从而使进一步的聚合因单体扩散受阻而受到限制,并伴随聚合转化率停滞平台（SCP）的产生.随后由于前期聚合累积的能量,使超分子结构完全解离.聚合温度越高,SCP持续时间越短.结果还表明,在正丁基锂引发剂中,存在一个以六元缔合结构为基础形成的更大的缔合体结构.原子力显微镜照片显示,超分子结构的直径分别为20～30nm和50～60nm.此外,在阴离子聚合过程中活性种的缔合结构只决定于初始引发剂的分子结构,而不同活性种缔合结构对阴离子聚合的链增长存在很大影响,从而解释了采用不同结构的锂系引发剂引发苯乙烯单体聚合时聚合速率存在巨大差异的原因.