一种新型有序超薄有机膜—自组膜

本文比较全面地综述了目前国际上研究比较热门的课题，一种新型有序超薄有机膜－自组膜。首先比较了自组膜和ＬＢ膜，主要从膜的特征和分类，膜的结构、表征技术等方面对自组膜的研究进行了综述。着重阐述了最有代表性的硫醇在金上的单分子层自组膜。     

澄清溶液体系二次生长法NaA型沸石膜的生长机制及膜厚的控制合成

用晶种涂层二次生长成膜法研究了在含水量不同的澄清溶液合成体系中NaA型沸石膜的生长及沸石膜厚度的控制合成.用SEM,TEM和XRD表征手段分析了沸石膜的形成过程和微结构.在载体表面不涂晶种而直接合成则不易形成连续沸石膜;用晶种涂层二次法可以很容易形成均匀的连续膜.合成液中水量的高低强烈影响沸石膜的生长速率、形成结构和膜的厚度.在高水量(水硅摩尔比为2000)的合成体系中沸石生长速率慢,膜主要通过晶种层中的晶粒长大,交织成膜,且膜只有一层结构;而在低水量(水硅摩尔比为750)的合成体系中沸石生长速率快,膜则通过晶种层表面晶粒向外生长、交织成膜,而膜具有两层结构.通过调变合成液的水量可有效地控制沸石膜层的厚度,并能制得非常均匀、连续的膜.     

一种具有“浮萍”结构的单分子膜与Langmuir—Blodgett多层膜

本文以St-DVB微凝胶/甲基丙烯酸两性接枝共聚物制成了一种新型“浮萍”结构的单分子膜,并转移制备了LB多层膜,对其单分子膜的性质、LB多层膜的二维有序结构及膜的热稳定性进行了较深入的研究。     

无机膜反应器中乙苯脱氢反应的研究

无机膜反应器中乙苯脱氢反应的研究钟丽，杨维慎，刘杰，丛铀，刘世河，林励吾（中国科学院大连化学物理研究所，大连１１６０２３）关键词膜反应器，乙苯，脱氢，微孔氧化铝膜将耐高温、耐腐蚀、结构较稳定的无机膜应用于高温催化反应，使反应与分离联为一体，已成为近年...     

氯化锂为添加剂制得的疏水聚偏氟乙烯不对称微孔膜的形态结构及其膜蒸馏性能

结合膜的形态结构研究了以 LiCl为添加剂制得的疏水 PVDF膜的膜蒸馏性能。与来用水溶液高分子添加剂制得的PVDF微孔膜相比,膜蒸馏性能有了较大提高,尤其具有更高的截留率。制得的微孔膜的蒸馏通量已接近商品膜的膜蒸馏通量,表明以LiCl为添加剂制得的PVDF疏水微孔膜是一种适用于膜蒸馏的较理想的疏水微孔膜。     

正渗透脱盐过程的核心——正渗透膜

淡水资源已成为战略性资源,未来和平与可持续发展将与净水及淡水的获得息息相关。正渗透技术是目前国际上最前沿、最具潜力的水净化和脱盐技术,因其能耗极低而成为该领域的研究热点。正渗透膜作为正渗透关键技术之一,已经引发了新一轮的研究热潮。本文以正渗透膜的分离性能为核心概述了正渗透膜的发展历程,按正渗透膜制备方法进行分类,分别介绍了近几年来相转化正渗透膜、薄层复合正渗透膜和化学改性正渗透膜中的主要和新兴膜材料、结构特点及研究进展等,最后探讨和展望了正渗透膜今后的研发方向。     

分子筛膜反应器的研究进展

分子筛膜具有规整的微孔结构(<1 nm), 耐高温高压、 抗有机溶剂, 在液相和气相小分子分离中受到广泛关注. 分子筛膜可以与催化反应耦合于一体构成膜反应器, 使反应过程与组分分离同时进行, 促进反应平衡移动, 达到反应强化的效果. 本文概述了近十年不同类型分子筛膜反应器在催化反应中的应用研究进展, 并对分子筛膜反应器未来的发展趋势进行了展望.     

燃料电池用跨温区质子交换膜材料研究进展

质子交换膜燃料电池(PEMFC)是一种电化学能量转换器件，能将燃料中的化学能转换为电能，具有高效、清洁、寿命长等优点，可应用于动力电池、固定式和便携式电源等领域。质子交换膜(PEM)是其中的关键部件，主要用于隔离阴阳两极和传递质子等。但当前质子交换膜燃料电池的发展面临着成本高、寿命不足等挑战。本文结合近年的研究热点，从质子传输机制出发将质子交换膜燃料电池分为磺酸功能化PEM和磷酸掺杂型PEM两大类，从主链结构的差异以及改性方法等方面综述近年来的研究进展，详细介绍了材料的化学结构、膜材料性能、电化学性能等，并针对现存的一些问题和不足对质子交换膜燃料电池今后的发展方向进行了展望。     

聚合物在离子选择电极上的应用

本文概述了聚合物膜离子选择电极的发展、制备、应用等方面的研究情况。分别对固态膜类和液膜类聚合物膜离子选择电极的优缺点和发展前景进行了分析,并讨论了聚合物在膜电极中的作用,以及聚合物的结构对膜电极性能的影响。     

高分子合金分离膜材料及结构研究进展

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。     

高分子结构与性能关系原理-结构层次的意义

高分子结构是高分子性能的重要物质基础,对其结构进行合理的划分,有助于准确把握高分子物理知识体系的内在脉络。高分子结构层次的划分不仅要思考静态时特定质点在空间的堆砌特征,而且也要考虑结构出现运动或是变化的基本单元。按照质点尺度的不同,高聚物的结构可以分为单一高分子结构(链结构)、多个高分子结构(凝聚结构)和多种高分子结构(织态结构)三个主要层次。其中,化学因素所确定的链结构层次包括相对分子质量以及构造、构型等同分异构体形式;物理因素所确定的结构层次为高分子局部质点集合在空间的堆砌和排列;链段是容易被忽视、但又是最为重要的运动(变化)单元。     

Microbial transformation of (+)-androsta-1 ,4-diene-3,17-dione by Cephalosporium aphidicola

Fermentation of (+)-androsta-1,4-diene-3,17-dione ([structure: see text]) with Cephalosporium aphidicola for 8 days yielded oxidative and reductive metabolites, androst-4-ene-3,17-dione ([structure: see text]), 17beta-hydroxyandrosta-1,4-diene-3-one ([structure: see text]), 11alpha-hydroxyandrosta-1,4-diene-3,17-dione ([structure: see text]), 11alpha-hydroxyandrost-4-ene-3,17-dione ([structure: see text]), 11alpha,17beta-dihydroxyandrost-4-ene-3-one ([structure: see text]) and 11alpha,17beta-dihydroxyandrosta-1,4-diene-3-one ([structure: see text]). The fermentation of [structure: see text] with Fusarium lini also yielded metabolites [structure: see text]. The structures of these metabolites were elucidated on the basis of spectroscopic techniques.     

Kinetic pathway to double-gyroid structure

We have investigated the structural development during order-order transitions to the double-gyroid (DG) phase of nonionic surfactant/water systems based on two-dimensional small-angle x-ray scattering patterns from highly oriented ordered mesophases. The lamellar (L) to DG transition proceeds through two intermediate structures, a fluctuating perforated layer structure having ABAB stacking and a hexagonal perforated lamellar structure with ABCABC stacking (HPLABC). For a hexagonally packed cylinder (H) to DG transition, we also observed the HPLABC structure as the intermediate phase, thus the HPLABC is an entrance structure for the DG phase. The hexagonal perforated lamellar (HPL) structure consists of hexagonally packed holes surrounded by the planar tripods, and the transition from HPL structure to the DG phase proceeds by rotation of the dihedral angle of connected tripods. A geometrical consideration shows that large deformations of HPL planes are necessary to form the DG structure from the HPLABC structure, whereas the transition from a HPL structure with ABAB stacking (HPLAB) to the DG structure is straightforward. In spite of the topological constraints, the HPLABC structure is observed in the kinetic pathway to the DG structure.     

A partition function algorithm for nucleic acid secondary structure including pseudoknots

Nucleic acid secondary structure models usually exclude pseudoknots due to the difficulty of treating these nonnested structures efficiently in structure prediction and partition function algorithms. Here, the standard secondary structure energy model is extended to include the most physically relevant pseudoknots. We describe an O(N(5)) dynamic programming algorithm, where N is the length of the strand, for computing the partition function and minimum energy structure over this class of secondary structures. Hence, it is possible to determine the probability of sampling the lowest energy structure, or any other structure of particular interest. This capability motivates the use of the partition function for the design of DNA or RNA molecules for bioengineering applications.     

三维纳米液膜沉积结构的模拟研究

基于三维动力学蒙特卡罗模型,再现了纳米液膜干燥后形成的双尺度沉积结构,探究了液体化学势、纳米粒子移动速率、液体临界蒸发率以及化学势锐度等参数对纳米液膜沉积结构的影响。结果表明,纳米液膜干燥时,液膜中的纳米粒子随着三相线移动自组装形成各种各样的沉积结构沉积在基板上。纳米液膜蒸发过程中,当液体蒸发达到临界蒸发率时液体化学势将发生突变,使其形成两种沉积结构。随液体初始化学势的增大,沉积结构逐渐变为均匀分布的密集网状结构。液体临界蒸发率越小,液体化学势突变后形成的沉积结构越明显。纳米粒子的移动速率越快,沉积结构中的枝状结构越少。化学势锐度对双尺度沉积结构的差异有很大的影响,锐度越大,两种沉积结构的差异越大。     

纳米粒子驱动受限环境下两嵌段共聚物/均聚物混合体系的自组装行为

采用含时金兹堡-朗道理论(time-dependent ginzburg-landau theory,简称TDGL)方法研究了纳米粒子(nanoparticles,简称NPs)掺杂的两嵌段共聚物/均聚物(AB/C)共混体系在球形受限下的自组装行为.在不同球形受限条件下,两嵌段共聚物/均聚物共混体系形成了多种丰富的形貌,如双螺旋结构、单螺旋结构、层状结构和洋葱环状结构等.当在以上前3种体系中掺杂纳米粒子后,体系结构发生了很大的变化.详细研究了纳米粒子的浓度和浸润强度对以上结构的影响.研究结果表明,通过调控纳米粒子的浓度和浸润性质,该共混体系实现了双螺旋结构→层状结构,单螺旋结构→双螺旋结构,层状结构→单螺旋结构等多种取向序的转变.对于洋葱环状结构,纳米粒子的加入对体系这一结构的影响不大.     

Equivalent potential of water molecules for electronic structure of glutamic acid

The fundamental importance of the electronic structure of molecules is widely recognized. To get reliable electronic structure of protein in aqueous solution, it is necessary to construct a simple, easy-use equivalent potential of water molecules for protein's electronic structure calculation. Here, the first-principles, all-electron, ab initio calculations have been performed to construct the equivalent potential of water molecules for the electronic structure of glutamic acid, which is a hydrophilic amino acid and is negatively charged (Glu(-)) in neutral water solution. The main process of calculation consists of three steps. Firstly, the geometric structure of the cluster containing Glu(-) and water molecules is calculated by free cluster calculation. Then, based on the geometric structure, the electronic structure of Glu(-) with the potential of water molecules is calculated using the self-consistent cluster-embedding method. Finally, the electronic structure of Glu(-) with the potential of dipoles is calculated. Our calculations show that the major effect of water molecules on Glu(-)'s electronic structure is lowering the occupied electronic states by about 0.017 Ry, and broadening energy gap by 12%. The effect of water molecules on the electronic structure of Glu(-) can be well simulated by dipoles potential.     

CdSe的电子结构和光学性质研究

CdSe是Ⅱ-Ⅵ族半导体材料中一种重要的半导体材料,它有闪锌矿和纤锌矿两种不同的结构,带隙较窄,具有优良的电光特性和广泛的应用前景,得到了人们的广泛关注[1-3].     

Computer-aided structure elucidation methods

Computer-aided structure elucidation methodology is discussed. Major processes involved in computer-aided structure elucidation systems are partial-structure elucidation, structure generation, and structure examination. For the three representative systems CONGEN, CASE, and CHEMICS, these processes are examined. There are four necessary conditions for automated chemical structure elucidation systems: reliability, width of application, ease of modification and portability.