基于双吡啶基双西佛碱通过氢键相互作用形成的有机超分子晶体

合成了双吡啶双西佛碱(bpbd)有机分子，并用该分子进行了超分子网络晶体的组装．X射线单晶结构分析表明：在bpbd晶体中存在着分子间氢键相互作用，该氢键由吡啶环上的N原子和西佛碱H—C—N基团上的H原子相互作用而成．每一个bpbd分子同另外4个bpbd分子通过氢键相连，构成了二维网状结构；在bpbd晶体中还存在分子间π…π相互作用，并导致一维分子柱的形成．二维氢键和一维π…π的协同作用，导致了三维超分子晶体的形成。     

基于多重氢键的超分子液晶研究

基于氢键的超分子液晶体系的研究是一个方兴未艾的充满活力的前沿研究领域,它在化学和生物体系中占据非常重要的位置。本文主要介绍了目前文献报道的基于二重以上氢键的超分子液晶体系的研究进展。     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注.本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基(D)与吡啶基(A)作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述.     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注。本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基（D）与吡啶基（A）作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述。     

基于氢键作用结合的超分子聚合物

非共价键结合的超分子聚合物由于其特殊的结构及性能引起了广泛的关注。本文在介绍超分子化学、氢键及超分子聚合物的基础上,主要综述了以氢键为结合力的多重氢键作用、羧基(D)与吡啶基(A)作用以及氢键与其它非共价键协同作用形成的超分子聚合物体系,并对超分子聚合物的研究现状及前景进行了评述。     

基于氢键的自组装超分子体系

氢键自组装超分子是超分子体系中相对较新颖和引人注意的领域,它在化学和生物体系中占据非常重要的位置。本文主要介绍目前文献报道的一系列由不同氢键缔合方式形成的自组装超分子。     

多孔氢键有机框架(HOFs):现状与挑战

氢键有机框架(HOFs)已经发展成为一类独特的晶态多孔材料,它一般是由有机或金属-有机构建单元通过分子间的氢键相互连接而形成的框架材料.由于氢键强度弱和柔性强,因此大部分HOFs的框架都比较容易坍塌.然而,通过合理地选择刚性且具有特定几何构型的构建单元、引入穿插或π-π作用和静电作用等其它分子间的作用力,稳定且多孔的HOFs也逐渐地被制备出来.与其它含有机组分的晶态多孔材料如金属-有机框架(MOFs)和共价有机框架(COFs)相比, HOFs具有自己的特点,例如:温和的合成条件、高度的结晶性、溶剂加工性、容易修复和再生等. HOFs的这些特点能够使其成为一类独特的功能多孔材料.本综述主要概述了稳定且多孔HOFs设计的一些基本原则,系统总结了构筑HOFs常用的超分子合成子以及脚手架,重点综述了近十年HOFs在气体吸附与分离、质子传导、异相催化、荧光和传感、生物应用、对映体拆分和芳香化合物的分离、环境污染物去除和有机结构测定等领域的重要进展.     

氢键结合超分子水凝胶的形成与结构调控

近年来,依靠单体单元间可逆和高度取向的非共价作用力形成超分子聚合物(supramolecularpolymer)得到广泛关注[1,2].在溶液中,超分子单体单元之间通过非共价键相互作用,形成三维网络结构并将有机溶剂或水包裹形成超分子凝胶[3,4].相对于聚合物凝胶,超分子凝胶具有以下优点.(1)生     

基于氢键的自组装超分子体系

氢键自组装超分子是超分子体系中相对较新颖和引入注意的领域，它在化学和生物体系中占据非常重要的位置。本文主要介绍目前文献报道的一系列由不同氢键缔合方式形成的自组装超分子。     

氢键识别超分子聚合物的新进展

近年来,由于氢键作用对聚合物的热力学性质、微观自组装、结晶及液晶行为的重要影响,氢键识别在超分子聚合物的分子设计与结构控制方面的应用受到广泛关注。本文系统介绍了氢键识别体系的类型与性质,以及分子结构、分子内氢键对氢键识别强度的影响,讨论了羧酸与吡啶间氢键识别体系、与核苷相关的氢键识别体系以及四重氢键识别体系在超分子聚合物中的最新应用,主要介绍了氢键识别超分子聚合物的合成、结构、性质及功能。     

通过氢键构筑的混合配体3D超分子及电化学性质

在水热条件下合成了配位聚合物[Co(H2O)6].[Co(phen)2(H2O)2]2·(BTC)2·24.6H2O(phen=1,10-邻菲罗林,BTC=均苯三甲酸),并通过元素分析,IR光谱,TGA和单晶X射线衍射对其进行了表征,结构表明该化合物属于单斜晶系,空间点群P2(1)/c.晶体的不对称结构单元中包含1个均...     

Synthesis and structures of two supramolecular complexes constructed via hydrogen bond linking

Two supramolecular complexes,[Ni(rac-L)]3[CrO4]2[ClO4]2-4H2O (1) and [meso-H2L]0.5[VO3]-0.16H2O (2) (L= 5,5,7,12,12,14-hexamethyl-1,4,8,11-tetraazacyclotetra-decane),have been prepared in an aqueous solu-tion,and detected by elemental analysis,IR,TG,and single crystal X-ray diffraction analyses. Com-pound 1 shows a one-dimensional hexagonal prism formed by the hydrogen bonding interactions between the secondary amines of rac-L and CrO42-anion/water molecules. Compound 2 displays a three-dimensional structur...     

Helical supramolecular aggregates based on ureidopyrimidinone quadruple hydrogen bonding

A series of mono- and bifunctional compounds 2-7, based on the ureido pyrimidinone quadruple hydrogen bonding unit, was prepared to study the mode of aggregation of these compounds in the bulk and in solution. Compounds 2-7 exhibit thermotropic liquid crystalline properties, as evidenced by differential scanning calorimetry and optical polarization microscopy. The presence of an ordered hexagonal discotic (D(ho)) phase of 2 a was confirmed by X-ray diffraction on an aligned sample. In chloroform, the bifunctional compounds form cyclic dimers at millimolar concentrations, and these dimers exist in equilibrium with linear species above a critical concentration, which may be from 6 mM to greater than 260 mM, depending on the structure of the spacer. Circular dichroism measurements in chloroform did not show a Cotton effect. Dodecane solutions of compounds 3, 4 b, and 7 b display a Cotton effect at the absorption band of the phenyl-pyrimidinone unit. Amplification of chirality was observed in mixtures of 7 a and 7 b, but not in mixtures of 4 a and 4 b, indicating that 7 a and 7 b form mixed polymeric aggregates with a helical architecture in dodecane solution, whereas 4 a and 4 b do not. The Cotton effect is lost upon increasing the temperature. Half of the helicity is lost at 25 degrees C for 3 and at 60 degrees C for 4 b, suggesting that 3, bearing the shorter spacer, forms less stable columns than 4 b. Compound 7 b loses half of its helicity at 45 degrees C. Compounds 2 b, 5, and 6 do not exhibit helical organization, as evidenced by the absence of Cotton effects.     

Hydrogen-bonded supramolecular polymer networks

The strong dimerizing, quadruple hydrogen-bonding ureido-pyrimidone unit is used to obtain reversible polymer networks. A new synthetic route from commercially available starting materials is described. The hydrogen-bonding ureido-pyrimidone network is prepared using 3(4)-isocyanatomethyl-1-methylcyclohexyl-isocyanate (IMCI) in the regioselective coupling reaction of multi-hydroxy functionalized polymers with isocytosines. ¹H- and ¹³C-NMR, IR, MS, and ES-MS analysis, performed on a model reaction using butanol, demonstrated the formation of the hydrogen-bonding ureido-pyrimidone unit in a yield of more than 95%. The well-defined, strong hydrogen-bonding ureido-pyrimidone network is compared with a traditional covalently bonded polymer network, a multi-directional hydrogen-bonded polymer network based on urea units, and a reference compound. The advantage of the reversible, hydrogen-bonded polymer networks is the formation of the thermodynamically most favorable products, which show a higher “virtual” molecular weight and shear modulus, compared to the irreversible, covalently bonded polymer network. The properties of the ureido-pyrimidone network are unique; the well-defined and strong dimerization of the ureido-pyrimidone unit does not require any additional stabilization such as crystallization or other kinds of phase separation, and displays a well-defined viscoelastic transition. The ureido-pyrimidone network represents the first example of a truly reversible polymer network showing these features. Furthermore, the ureido-pyrimidone dimerization is strong enough to construct supramolecular materials possessing acceptable mechanical properties. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 3657–3670, 1999     

Strategies for hydrogen storage in metal--organic frameworks

Increased attention is being focused on metal-organic frameworks as candidates for hydrogen storage materials. This is a result of their many favorable attributes, such as high porosity, reproducible and facile syntheses, amenability to scale-up, and chemical modification for targeting desired properties. A discussion of several strategies aimed at improving hydrogen uptake in these materials is presented. These strategies include the optimization of pore size and adsorption energy by linker modification, impregnation, catenation, and the inclusion of open metal sites and lighter metals.     

Self‐healing polyurethane based on disulfide bond and hydrogen bond

Tough and transparent polyurethane networks with self‐healing capability at mild temperature conditions were successfully prepared in a 1‐pot procedure. The self‐healing ability of synthesized polyurethane comes from the covalent disulfide metathesis and non‐covalent H‐bonding. The mechanical testing indicates that disulfide metathesis reforms the covalent bonds on a longer time scale, while H‐bonding gives rise to a healing efficiency of around 46% in the early healing processing. The compromise between mechanical performance and healing capability is reached by tailoring the concentration of disulfide. The tensile strength of the sample with 100% self‐heal efficiency can get to 5.01 MPa, which can be explained by higher mobility of polymer chain under ambient temperature from creep testing.     

Anion-templated supramolecular C3 assembly for efficient inclusion of charge-dispersed anions into hydrogen-bonded networks

The binding properties and conformational adaptability of a known nitrate/sulfate receptor N,N'-3-azapentane-1,5-bis[3-(1-aminoethylidene)-6-methyl-3H-pyran-2,4-dione] (L) toward various charge-dispersed monoanions (HSO(3)(-), ClO(4)(-), IO(4)(-), PF(6)(-), and SbF(6)(-)) are considered. These anions template the folding of three HL(+) species through a self-assembly process into a new hollow supramolecular trication. During the self-assembly, all strong hydrogen-bond donors of the podand become coordinatively saturated by interactions with the oxo functionalities from other HL(+) molecules. In that way, only the weak hydrogen-bond-donating groups in the exterior part of the receptor are accessible for anion binding. The investigated anions are accommodated in the hydrophobic pockets of the isomorphous hydrogen-bonded frameworks, which serve as a basis for selective crystallization from the highly competitive anion/solvent systems. This behavior is discussed in terms of size and geometry of the anions as well as the receptor's coordination capabilities to provide the most favorable surroundings for guest inclusion both in solution and in the solid state.     

Tuning reversible supramolecular polymer properties through co-monomer addition

Unlike most low molar mass organogelators, which form strong gels due to the entanglement of strong molecular aggregates such as crystalline fibres, a few reversible supramolecular polymers form viscoelastic solutions due to the formation of both rigid and dynamic filaments. By using three different bisureas which self-assemble according to the same hydrogen-bonding pattern and form such rigid reversible supramolecular polymers, we have shown that it is possible to finely tune the properties of the resulting solutions. The critical temperature below which viscoelastic solutions are obtained and the viscosity of the dilute solutions can be adjusted by changing the co-monomer content. This clearly facilitates gel formulation, which is an important step as far as applications are concerned.

By using three different bis-ureas which self-assemble according to the same hydrogen bonding pattern and form rigid reversible supramolecular polymers, we show that it is possible to finely tune the properties of the resulting viscoelastic solutions.     

A pH-responsive cleavage route based on a metal-organic coordination bond

The physical or chemical event that generally causes stimuli responses is limited to the formation or destruction of secondary forces, such as hydrogen bonding, hydrophobic effects, electrostatic interactions, and simple reactions. Here, pH-responsive behavior of metal-organic coordination bonding, which is intrinsic to natural systems (e.g., transferrin recycling in cells), is becoming a strong candidate for a new stimulus-responsive route. We have designed a simple pH-responsive release system by integrating a metal ion and ligand or self-assembling these species with biodegradable host molecules to form nanoparticles with "metal-ligand" or "host-metal-ligand" architectures. The cleavage of either or both the "metal-ligand" or the "host-metal" coordination bond in response to pH variations causes significant damage to the nanoparticles and the subsequent release of ligand molecules under designated pH conditions.