高压下的原子和分子行为

近些年,高压化学的研究取得了非常多的成果。本文从基础化学原理出发,讨论高压对原子轨道能量和化学键的影响。高压下,原子轨道能量会发生改变,从而导致核外电子在轨道间的重新排布,影响到元素的化学性质。于分子而言,高压下分子晶体会发生相变,不饱和化合物会发生自聚,饱和化合物则有可能金属化。     

金属表面化学反应的直接观察

介绍了表面化学中对金属表面化学反应研究的新动态和最新进展。     

均相化学反应体系的Monte-Carlo计算机模拟

根据反应速率的碰撞理论及反应独立共存原理,对包括振荡反应在内的均相化学反应的计算机模拟进行了探讨,在系统讨论有关Moote-Carlo模拟问题中,着重论述了模拟中分支反应与有效碰撞数的关系及计算机时间与实际反应时间的换算问题。提出了通用于各种均相化学反应的模拟算法,并成功地用于化学振荡反应机理的探讨。     

分子阵列研究

小分子化合物可以调节生物学过程,是研究活性生物大分子特别是蛋白质以及药物的重要工具,而高通量筛选是发现活性分子的重要方法.分子阵列是近年来新出现的一种高通量筛选技术,上面含有成千上万种组合合成的化合物以及天然产物,可以用于发现新的先导化合物,以及筛选已有的先导化合物.现在分子阵列已经成功应用于蛋白分析和先导化合物的发现等许多领域.本文综述了近年来分子阵列的构建过程、原位合成和非原位合成等各种固定化策略以及荧光免疫检测、表面等离子体共振成像技术等检测手段,并介绍了化学分子印刷阵列方法,最后总结了分子阵列的应用,并对分子阵列在我国中药发展等方面将起到的潜在作用作了展望.     

分子晶体中的几种分子间相互作用

描述了ＨＥＫ－ＤＤＱ，［Ｃｏ（Ｃ_５Ｈ_５）_２］［Ｎｉ（ｄｍｉｔ）_２］，ＢＢＢＴ－ＤＴＴ三个晶体结构中的π…π；Ｓ…Ｓ；Ｂｒ…Ｂｒ分子间相互作用，讨论了分子晶体中的分子间相互作用的材料化学意义。     

聚合物/富勒烯共混体系双分子穿插对有机体相异质结太阳能电池性能的影响

有机体相异质结太阳能电池有源层形貌直接影响器件能量转换效率.在聚合物/小分子共混体系中,当小分子尺寸小于聚合物侧链间距时,且与聚合物相互作用能形成基态-电荷转移态复合物时能够形成双分子穿插结构.双分子穿插结构改变了共混体系的薄膜形貌,不利于器件的光电转换过程.本文从双分子穿插结构形成过程入手,论述了双分子穿插行为对共混体系结晶行为及相分离行为的影响,以及对器件光电转换过程中激子扩散与分离及载流子传输等物理过程的影响;详细阐述了现阶段抑制双分子穿插行为的化学、物理方面的主要方法及相关原理.同时,我们进一步提出了该领域尚待解决的问题并对其发展前景进行了展望.     

分子阵列研究进展

小分子化合物可以调节生物学过程,是研究活性生物大分子（特别是蛋白质）以及药物的重要工具,而高通量筛选是发现活性分子的重要方法。分子阵列是近年来新出现的一种高通量筛选技术,上面含有成千上万种组合合成的化合物以及天然产物,可以用于发现新的先导化合物,以及筛选已有的先导化合物。现在分子阵列已经成功应用于蛋白分析、先导化合物的发现等许多领域。本文综述了近年来分子阵列的构建过程,原位合成、非原位合成等各种固定化策略以及荧光免疫检测,表面等离子体共振成像技术等检测手段,并介绍了化学分子印刷阵列方法,最后总结了分子阵列的应用,并对分子阵列在我国中药发展等有方面将起到的潜在作用作了展望。     

乙炔高压化学的开拓者——德国有机化学家列培

列培(Walter Julius Reppe, 1892 1969)生于绍林根(T huringen),高级中学毕业后入耶拿大学学习2年,1912年转入慕尼黑大学,因第一次世界大战爆发而服兵役5年,战后复学于慕尼黑大学,在迈尔( Kurt Hans M eyer, 1884 1952瑞士化学家)教授的指导下,一年后以“硝酸的烯丙基衍生物的阶段性还原”的研究获博士学位。     

高压下聚合物及其复合体系的结构与性能研究进展

随着科学技术的进步,材料科学有了很大的发展,其中高分子材料的发展应用尤为迅速。许多高分子材料在新的环境下结构与性能之间的关系都有待于研究。因此,了解它们在一些极端条件下（如高温高压、低温低压等）,结构与性能之间的变化规律是十分必要的。高压对聚合物材料的结构与性能有较大的影响。国内外学者主要对聚烯烃、聚酯、聚酰胺等聚合物及其复合体系的高压结晶和高压退火行为进行了一系列研究工作。本文介绍了这一领域的研究概况和最新进展。     

超分子体系的物理化学研究进展

本文介绍了超分子化学领域的研究进展, 评述了其中与物理化学有关的研究成果, 并从化学热力学、电化学、化学动力学、胶体与界面化学等几个主要方面加以讨论, 描述了超分子物理化学的基本框架。     

聚合物在高压下的结构、形态和性能（下）

聚合物在高压下的结构、形态和性能（下）张雄伟，黄锐（成都科技大学塑料工程系，成都，６１００６５）在上篇中我们介绍了结晶性聚合物在高压下结晶的结构和形态。本篇将介绍聚合物在高压下的结晶动力学和热力学以及聚合物在高压下的退火等方面内容。２高压结晶动力学研...     

高压下MgO熔化特性的分子动力学模拟

Molecular dynamics simulation was used to study the melting of MgO at high pressures. The melting temperature of MgO was accurately obtained at elevated temperature and high pressure after corrections based on the modern theory of melting. The calculated melting curve was compared with the available experimental data and other theoretical results at the pressure range of 0-135 GPa. The corrected melting temperature of MgO is in good agreement with the results from Lindemann melting equation and the twophase simulated results below 15 GPa.     

A High Pressure Study on NH4Pb2Br5 Type Compounds Part II: Electronic Structure and Changes under High Pressure

In this work, we present a theoretical study (based on DFT‐calculations) of the electronic properties of compounds crystallising in a NH₄Pb₂Br₅ type structure in a wide pressure range. The main focus of this study is to elucidate the nature of bonding of the ns²‐cations at ambient and elevated pressure. For a better understanding of the structure and bonding, the DOS of these compounds are evaluated and discussed on the basis of a simple model assuming mainly ionic interactions. The calculations are complemented by an orbital analysis using the crystal orbital Hamilton population (COHP) and an analysis of the electronic density topology with the electron localisation function (ELF). Structural and theoretical investigations give results that are in excellent agreement: The DFT‐calculations confirm the existence of bonding interactions between the ns²‐cations at elevated pressure. Our study indicates that the “character” of the additional electron pair changes with increasing pressure from nonbonding to bonding in agreement with a simple model system of two interacting ns²‐cations.     

High Pressure Study of NH4Pb2Br5 Type Compounds. I Structural Parameters and Their Evolution under High Pressure

We have investigated the nature of the interactions of ns²‐cations and the possible structure‐determining role of the ns²electron pair at ambient and high pressure in several AB₂X₅ (A = K, Rb, Cs, In, Tl; B = Sn, Pb, Sr; X = Cl, Br, I) compounds. Structural parameters are obtained by high pressure x‐ray diffraction as well as by quantum mechanical methods (DFT‐GGA‐calculations). The structural parameters at ambient and high pressure are discussed and compared to those of Tl₅Se₂I crystallising in the antitype structure. Short cation—cation distances in the NH₄Pb₂Br₅ type structure enable direct cation—cation interactions and the existence of an ns²‐cation in the B‐position is crucial for the stability of these structures. The effect of pressure on the structural parameters of these compounds gives new insights into the interactions of lone pair cations. The pronounced decrease of the cation—cation distances with pressure points to strongly increasing bonding interactions between the lone pair cations.     

高压条件下的凝聚态化学

本文介绍了高压条件对凝聚态物质电子结构和晶体结构的影响,其中包括高压对元素外层电子结构、能带结构和晶体缺陷的影响,高压导致的原子配位数的增加、元素非正常氧化态、结构相变和态变。同时从十个方面介绍了高压条件下凝聚态物质间的化学反应,最后对高压条件下凝聚态化学未来的发展做了展望。     

MCM-48介孔分子筛的高压合成

采用正硅酸乙酯（TEOS）作硅源,十六烷基三甲基溴化铵（CTAB）为模板剂,在高压 （约7 MPa）和373 K下合成了MCM-48介孔分子筛.用XRD、氮气吸附及29Si MAS NMR对样品 进行了表征.与常压合成的相比,高压下合成的MCM-48具有更高的热稳定性和水热稳定性.2 9Si MAS NMR结果表明,高压有利于分子筛孔壁的聚合,导致分子筛结构更加完善,从而使 其具有更高的稳定性.     

High Spin and Anisotropic Molecules Based on Polycyanometalate Chemistry

 This paper points out some recent achievements in the chemistry and physics of high spin and anisotropic molecules based on polycyanometalate complexes. Following a step by step synthetic strategy and using a localized electron orbital model, isotropic high spin molecules were obtained with ground spin states ranging from S = 9/2 to 27/2. In the same way, anisotropic molecules with various nuclearities (bi, tri, tetra, hexa, and hepta-nuclear complexes) have been synthesized. Mixing these two approaches, it has been possible to obtained anisotropic high spin molecules that behave as single molecule magnets. The paper reviews some of the steps that lead to these findings and some of the prospects opened in the field of single molecule magnets. Corresponding author. E-mail: marvaud@ccr.jussieu.fr Received July 19, 2002; accepted July 23, 2002     

Ab Initio High Pressure Investigations of InI

The high pressure behaviour of InI is studied by DFT‐calculations and compared with experimental data. The existence of a 5s² electron pair in In⁺ represents an unfavourable bonding situation for high symmetry structures because of effective closed shell repulsion. Since cations with a ns² electron pair are highly polarizable and the electronic situation is more favourable in the low symmetry structure InI prefers a TlI‐type structure at ambient pressure. A pressure induced transition to the more densely packed high symmetry CsCl‐type structure takes place at about 19 GPa according to our calculations. At ambient pressure the interactions are predominantly ionic. However with increasing pressure the distances between In⁺ cations in the TlI‐type structure diminish drastically, mainly due to the changing space requirement of the lone electron pair. Apart from ionic interactions further bonding interactions between the In⁺ cations occur. At elevated pressure the electron localization function (ELF) as well as the band structure diagrams suggest metallic bonding between the In⁺ within the zigzag chain, i. e. increasing bonding interactions between the In⁺ cations due to the electron pair and its s‐p‐mixing. At ambient pressure In‐In interactions are rather weak and the space requirement of the lone electron pair mainly determines the characteristic arrangement of the ions. At elevated pressure the In‐In interactions become stronger and stabilise themselves additionally the specific structural arrangement.     

Combinatorial Synthesis of Small Organic Molecules

Combinatorial synthesis has developed within a few years from a laboratory curiosity to a method that is taken seriously in drug research. Rapid progress in molecular biology and the resulting ability to determine the activity of new substances extremely efficiently have led to a change in paradigm for the synthesis of test compounds: in addition to the conventional procedure of synthesizing one substance after another, new methods allowing simultaneous creation of many structurally defined substances are becoming increasingly important. A characteristic of combinatorial synthesis is that a reaction is performed with many synthetic building blocks at once—in parallel or in a mixture— rather than with just one building block. All possible combinations are formed in each step, so that a large number of products, a so-called library, is obtained from only a few reactants. Several methods have been developed for combinatorial synthesis of small organic molecules, based on research into peptide library synthesis: single substances are produced by highly automated parallel syntheses, and special techniques enable targeted synthesis of mixtures with defined components. Many structures can be obtained by combinatorial synthesis, and the size of the libraries created ranges from a few individual compounds to many thousand substances in mixtures. This article gives an overview of the combinatorial syntheses of small organic molecules reported to date, performed both in solution and on a solid support. In addition, different techniques for identification of active compounds in mixtures are presented, together with ways to automate syntheses and process the large amounts of data produced. An overview of pionering companies active in this area is also given. The final outlook attempts to predict the future development of this exponentially growing area and the influence of this new thinking in other areas of chemistry.