基于多酸/嵌段共聚物的刺激响应性杂化功能材料

多酸具有多种拓扑结构和优异的理化性质,在光、电、磁、催化、生物医药等领域具有广阔的应用前景,在材料制备中常通过将多酸引入到有机体系构筑杂化材料来改善其加工性能.在有机分子中,嵌段共聚物具有良好的加工性、刺激响应性以及拓扑结构所赋予的特殊的自组装性能,是非常有潜力的一类杂化材料构筑基元.将多酸和嵌段共聚物作为自组装基元构筑杂化材料,能够将二者的优点相结合,同时开发出新的性能.多酸和嵌段共聚物的杂化可以通过共价键和非共价键2种方式实现,前者稳定性好,后者灵活简单.本文着眼于通过非共价键方式构筑的杂化体系,主要介绍了杂化体系的构筑策略以及刺激响应性.     

π-共轭纤维状杂化纳米结构的精准构筑与功能化

共轭聚合物因在电致发光材料、场效应晶体管等领域具有潜在的应用前景而受到人们的广泛关注。通过π-共轭聚合物的可控组装实现纳米纤维结构的精确构筑一直是提升材料性能的研究方向和挑战之一。近来,中国科学院上海有机化学研究所黄晓宇、冯纯课题组将非共价作用与活性结晶驱动自组装相结合,实现了多组分和多功能的以π-共轭对苯撑乙烯撑寡聚物(OPV)为核的纤维状杂化纳米结构的精确构筑及选择性功能化。利用"自晶种"(self-seeding)和活性"种子增长"(seeded growth)制备了以OPV为核,不同壳层的三嵌段和五嵌段单分散纳米纤维,并实现了对纤维各个嵌段长度的控制。利用聚2-乙烯基吡啶(P2VP)壳层作为后功能化锚点,可将无机纳米粒子(CdTe量子点、Au、Ag和Fe3O4纳米粒子)、聚合物球形胶束、SiO2/TiO2层负载在纤维状胶束的P2VP壳层中,并可单独对含有不同壳层的多嵌段纤维状胶束的P2VP壳层进行选择性修饰。这为多组分和多功能的π-共轭杂化纳米纤维状结构的高效构筑提供了一条新途径。     

制备有机-无机杂化纳米材料的研究进展

有机-无机杂化纳米材料由于小尺寸和兼具有机、无机材料的各种优良性质,在许多领域都有巨大的应用潜质。本文介绍了模板法、嵌段聚合物自组装、含特殊官能团的乙烯基单体直接聚合法等制备纳米有机-无机杂化材料的方法,并对各自的特点进行了说明。     

多金属氧簇与倍半硅氧烷簇构筑的簇-簇杂化分子的合成及自组装结构

以Wells-Dawson型多金属氧簇(POM)与T₈型倍半硅氧烷簇(POSS)为构筑单元,通过点击化学反应制备了一种由共价键连接形成的、新型的纳米簇-簇杂化分子(POM-2POSS),并采用核磁共振(NMR)、质谱(MS)和红外光谱(IR)对产物化学结构进行了表征. 由于两个POSS簇连接在POM簇的同一侧,分子呈现“V”形. 同时,利用X射线衍射(XRD)及透射电子显微镜(TEM)表征了簇-簇杂化分子在本体中通过自组装过程形成的超分子结构,结果表明该簇-簇杂化分子形成了有序的层状结构,周期仅为5.1 nm. 本研究获得结果对以这类纳米簇为构筑单元构筑新型杂化分子以及通过自组装过程形成的、有序超分子结构的新型杂化材料的设计及制备提供了一个新的思路.     

功能性POSS聚合物及其应用

多面体低聚倍半硅氧烷(POSS)是一类具有纳米分子尺寸和有机-无机杂化结构的化合物。这种以无机Si—O—Si键组成的框架为核,外围被有机取代基所包围的特殊结构,具有独特的物理性质和化学反应性。采用物理或共聚的方法使其与其他聚合物复合,得到具有特殊功能的有机/无机纳米复合高分子材料,可用于诸多领域,近年来备受关注。本文在介绍POSS分子结构特点的基础上,详细阐述POSS聚合物的合成方法、特点和功能性,着重讨论了POSS在超疏水表面与抗结冰涂层、两亲聚合物、形状记忆材料中的应用及研究现状,并展望了功能性POSS聚合物的发展前景。     

一维纳米纤维构筑的导电聚合物三维结构及其可控的浸润性

微/纳米结构的导电聚合物由于具有高导电性、易合成以及优异的环境稳定性从而在许多先进的研究领域备受关注,并有望在分子导线、化学和生物传感器、发光器件等领域获得广泛应用。 特别是,复杂的三维自组装结构在获得高性能和功能化的材料方面提供了巨大的潜在应用价值。本文主要介绍了我们利用胶束的软模板和自组装驱动力的协同效应,实现由一维纳米结构组装的三维微米结构导电聚合物方面的研究进展。该制备技巧在于低表面自由能的含氟有机酸具有软模板、掺杂剂、自组装驱动力,以及诱导超疏水性的多重作用实现导电聚合物三维结构的组装和多功能化。介绍了利用环境湿度调整分子的自组装驱动力,实现导电聚合物由一维纳米结构向三维微米结构的组装。此外,还介绍了利用导电聚合物可逆的化学掺杂/脱掺杂机制,实现导电聚合物表面浸润性的可逆转化。最后介绍了在液/液/固三相体系中,通过外加电场刺激,可实现油滴在导电聚合物表面的浸润性和黏附力的控制。     

聚苯乙烯-丙烯酸嵌段共聚物在Ca~(2 )或乙二胺存在下的自组装行为

近 1 0年来 ,人们对于具有纳米尺度聚合物自组装结构的研究日益增多 .其中 ,嵌段共聚物在选择性溶剂中的胶束行为的研究非常引人瞩目 [1～ 3] .其表现出诸多常规尺寸所不具备的特殊性能 ,使得纳米胶束不仅在理论上有研究价值 ,而且在材料化学、生物医学和环境科学等领域都具有广阔的应用前景 .Ma等[4 ] 对聚丙烯酸和聚苯乙烯接枝共聚物的研究发现聚合物接枝率和聚合物浓度以及溶液离子强度对胶束结构有影响 ;Zhang等 [1,5] 对不同嵌段比例的苯乙烯 -丙烯酸嵌段共聚物的自组装行为的研究 ,发现不同嵌段比例所对应的纳米结构不同 ;而胶束表面…     

多酸-有机聚合物超分子自组装杂化材料

多酸具有多样的拓扑结构和优异的理化性质,在催化、光电材料和药物等领域显示出广阔的应用前景。多酸-有机聚合物超分子自组装杂化材料不仅有效融合了多酸丰富的功能特性和有机聚合物良好的加工性,而且其有序的自组装结构还赋予材料更多优异的功能调控性。静电复合、氢键作用、共价键连等超分子策略是将多酸引入到聚合物基质中的有效方法。本文总结了多酸-有机聚合物超分子杂化材料近几年的最新研究进展,重点介绍了这类杂化材料的构筑策略、其有序的自组装行为以及超分子功能特性的调控等。     

两嵌段聚合物自组装微观形貌中的网状结构

嵌段聚合物由于不同嵌段热力学不相容而形成微观相分离,进而发生自组装排列成规则有序的微观结构,其中网状结构是自组装微观结构中的复杂结构,具有令人瞩目的特性,在纳米科技领域应用价值极高,备受各国研究者的青睐。本文介绍了嵌段聚合物自组装原理和网状结构的特点,重点综述了两嵌段聚合物自组装结构中常见的三种网状结构的发展、制备方法以及在纳米科技中的应用,并指出当今网状结构的研究热点,预测该领域的发展趋势。     

POSS聚合物及其新进展

POSS 作为一种特殊的有机/无机杂化纳米构件备受关注。本文总结了近几年有关探索POSS聚合物结构与性能之间关系的研究进展，并重点综述了POSS在有机半导体材料领域的应用。     

Advances in Template Prepared Nano‐Oxides and their Applications: Polluted Water Treatment,Energy, Sensing and Biomedical Drug Delivery

The nano‐oxide materials with special structures prepared by template methods have a good dispersion, regular structures and high specific surface areas. Therefore, in some areas, improved properties are observed than conventional bulk oxide materials. For example, in the treatment of dye wastewater, the treatment efficiency of adsorbents and catalytic materials prepared by template method was about 30 % or even higher than that of conventional samples. This review mainly focuses on the progress of inorganic, organic and biological templates in the preparation of micro‐ and nano‐ oxide materials with special morphologies, and the roles of the prepared materials as adsorbents and photocatalysts in dye wastewater treatment. The characteristics and advantages of inorganic, organic and biological template are also summarized. In addition, the applications of template method prepared oxides in the field of sensors, drug carrier, energy materials and other fields are briefly discussed with detailed examples.     

Bioinspired synthesis and preparation of multilevel micro/nanostructured materials

In this review, some living organisms with multilevel hierarchical micro/nanostructures and related special properties are briefly introduced. The unique properties of organisms are mostly related to their special hierarchical micro/nanostructures. Inspired by nature, many zero-dimensional and one-dimensional micro/nanomaterials with biomimic or bioinspired multilevel micro/nanostructures have been successfully synthesized and prepared in recent years. Compared with traditional solid materials, the synthesis and preparation of these multilevel structured materials is more ingenious. Moreover, these kinds of multilevel micro/nanomaterials show fantastic properties in many fields because of their micro/nanoscale complex interior structures, whichmay be intended for application in catalysis, Li-ion batteries, biomedicines, sensors, and others.     

生物医用类环糊精/聚合物(准)聚轮烷

环糊精及其衍生物具有“内疏水、外亲水”的特殊分子结构,可与许多客体分子包结形成包合物。利用环糊精与聚合物的包结作用构建稳定、结构可控并具有广泛应用前景的生物医用材料是材料及医学界研究的焦点之一。本文介绍了环糊精基(准)聚轮烷的概念及其组装驱动力,同时围绕由环糊精和聚合物组装形成的(准)聚轮烷在生物医用方面的研究包括药物载体(如超分子凝胶、超分子胶束、超分子纳米囊泡、药物键合(准)聚轮烷、刺激响应型(准)聚轮烷等)、基因载体、多重识别与靶向、形状记忆材料及其它相关领域工作进展作一概述。     

金属-有机骨架材料及其在催化反应中的应用

金属-有机骨架(metal-organic frameworks, MOFs)材料是由金属离子和有机配体通过自组装而成的具有多孔结构的特殊晶体材料。由于其种类的多样性、孔道的可调性和结构的易功能化,已在气体的吸附和分离、催化、磁学、生物医学等领域表现出了诱人的应用前景。本文介绍了MOFs材料的类型和常用的合成方法,综述了近年来MOFs材料在催化领域的应用,特别是以MOFs材料中骨架金属作为活性中心、骨架有机配体作为活性中心和负载催化活性组分的催化反应,并对MOFs材料的催化应用趋势做了展望,以期对MOFs材料的催化性能有比较全面的认识。     

多孔碳材料的模板法制备、活化处理及储能应用

简要介绍了广义模板法制备多孔碳材料的研究现状,并进一步阐述了应用传统活化法对模板法制备的多孔碳材料进行结构调控. 最后,详细介绍了多孔碳材料在氢气吸附以及超级电容器用电极材料等储能领域的应用.     

柱芳烃的合成与应用

综述了近四年来新型超分子主体化合物柱芳烃的合成、发展和应用.其中,柱芳烃及其衍生物的合成主要有两种有机化学合成策略,即"先成环后修饰"和"先修饰后成环".由于这类新型主体化合物具有非常特殊的空间结构和理化性质,目前,它主要应用在主客体包合与分子识别、自组装体系的构筑和智能材料等领域.     

手性金属有机骨架材料的合成及其在对映异构体选择性分离中的应用

手性现象在自然界中广泛存在,手性分离在药物研发、农用化学、药理学、环境科学和生物学等诸多领域具有重要意义。手性金属有机骨架化合物材料(MOFs)是一类具有特殊拓扑结构和可设计的孔道结构的新型多孔材料,加之其比表面积高、孔隙率大、热稳定性良好和溶剂耐受性好等特性,使得MOFs在分析化学领域的应用与研究日益深入。本文简要综述了手性MOFs的合成方法,着重讨论了手性MOFs在对映异构体选择性分离方面的应用及相关机理,最后对该类材料的发展前景做了展望。     

Optical manipulation with nanoscale chiral fields and related photochemical phenomena

Chiral light-matter interaction occurs when the system consists of the matter and the light has a chiral structure, which is generically called the chiro-optical effect. Circular dichroism and optical rotation are representative spectroscopic methods based on chiro-optical effects. Chiro-optical effects have been widely utilized to detect chiral materials in the system. The chiro-optical effect also has the potential to create chiral materials from achiral materials and chiral optical fields, and to generate chiral optical fields from chiral matter systems. To achieve that, the design and observation of chiral optical field structures are essential. In this article, we describe local chiral optical fields generated in the peripheries of nanomaterials (typically metal nanostructures) irradiated with light. We summarize basic characteristics of nanoscale local chiral optical fields, methods to observe/control the chiral optical field structures at nanomaterials. Then some chemical, optical, and mechanical effects of designed chiral optical fields are described. Chiral nanostructures were created from achiral nanomaterials combined with circularly polarized light. Nucleation of chiral crystals of achiral molecules was achieved by circularly polarized light with the aid of plasmonic materials. Circularly polarized luminescence was observed from achiral fluorescent molecules conjugated with chiral plasmonic nanostructures. On mechanical characteristics, optical forces exerted on chiral materials were found to be dependent on the handedness of incident circularly polarized light, which can be utilized to discriminate the chirality of the material. The concept can be further generalized to the spin-dependent asymmetric light-matter interactions, which will create not only the molecular- and nano-scale chiral structures but also various novel functions of materials that are correlated with the handedness degree of freedom.     

Polymer brushes here,there, and everywhere: Recent advances in their practical applications and emerging opportunities in multiple research fields

Bottom‐up surface processing with well‐defined polymeric structures becomes increasingly important in many current technologies. Polymer brushes, that is, assemblies of macromolecules tethered at one end to a substrate, provide an exemplary system of materials capable of achieving such a goal. While the focus in the past decades has been mostly on their synthetic aspects and the in‐depth study of their interesting properties, from several years now the core area of research has already started to shift towards specific practical applications. Ample functional versatility and relative ease of preparation are special strengths of polymer brushes, lending them a strong interdisciplinary character. To this end, this work is entirely dedicated to bringing together the latest research on applications of polymer brushes in multiple research fields. The aim of this review are twofold: first, to give a critical discussion of the current status of development of application‐oriented research on polymer brushes, and second, to inform the reader as to what can be done with polymer brushes in multiple research fields. It is therefore hoped that the juxtaposition of perspectives from different disciplines in one place will stimulate and contribute to the ongoing process of cross‐fertilization that is driving this fascinating and emerging area of polymer science. © 2012 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2012     

Functional modification,self-assembly and application of calix[4]resorcinarenes

As a special subset of calix[4]arene, calix[4]resorcinarene is an excellent molecular platform which could be modified by introducing functional groups to multiple sites at the upper and lower rims. There are mainly three ways to build functionalized calix[4]resorcinarene derivatives: (1) modification on the C-2 sites of calix[4]resorcinarenes; (2) modification on the phenolic hydroxyl groups of calix[4]resorcinarenes; (3) modification on the bridging methylenes at lower rim of calix[4]resorcinarenes. Functionalized calix[4]resorcinarene derivatives play an important role in the development of self-assembly chemistry, among which hydrogen bonding and metal coordination are the two most common interactions to obtain multicomponent structures. Moreover, due to the excellent topological structures and various active substituents of functionalized calix[4]resorcinarene derivatives, their applications in various fields, such as nanoparticles, catalysts, fluorescent materials, and sensors, have been briefly presented in this paper.