在H－ZSM－5沸石上甲醇转化为汽油的初始产物分布

在Ｈ－ＺＳＭ－５沸石上甲醇转化为汽油的初始产物分布姜玄珍（浙江大学化学系，杭州３１００２７）Ｒ．Ｆ．Ｈｏｗｅ（新南威尔士大学物理化学系，澳大利亚）关键词Ｈ－ＺＳＭ－５沸石，甲醇转化汽油，产物分布以氢型ＺＳＭ－５沸石作催化剂转化甲醇为汽油（ＭＴＧ），在...     

退火温度对钙钛矿型氧化物La0.68Pb0.32FeO3的结构及其乙醇气敏性能的影响

采用sol—gel法，分别在不同温度下退火2h，制得一系列纳米氧化物La0.68Pb0．32FeO3粉体，并测定了该材料对乙醇的气敏性能。随退火温度的升高，所得样品逐渐向单一钙钛矿结构转化。应用Scherrer公式对退火温度分别为200，400，600，800，1000℃的样品粒径进行了计算，样品粒径依次为11．5，13．6，16．4，20．0，25．3nm。这说明，随着退火温度的升高，样品粒径逐渐增大。对乙醇气敏性能的测定结果表明，随退火温度的升高，材料对乙醇的最佳灵敏度先升高、又降低，退火温度为800℃的样品最佳灵敏度达到51．7。     

无机螺旋体超分子配合物的组装、应用和结构转化研究进展

简述了近年来报道的具有新颖结构和性能的无机螺旋体超分子配合物的组装、应用和结构转化方面的最新进展,并展望了无机螺旋体的发展前景及其开发应用潜力。     

强冲击加载条件下的钨合金的界面研究

借助定量金相、扫描电子显微镜、透射电子显微镜等微观分析手段对钨质量分数为９３％的钨合金在１５～５０ＧＰａ冲击压力下微观结构响应性态进行了考察，发现了一些钨合金所特有的现象，即钨颗粒与粘结相交界处出现成分迁移，新相析出；并结合断口分析，探讨了钨合金在冲击作用下发生断裂的微观特征与韧脆转化间的关系及其物理本质。     

导电二维配位聚合物框架材料在能源存储及转化领域的应用

配位聚合物框架材料具有高的比表面积、丰富的孔结构和金属配位中心,一直以来被视为能源领域的潜在电极材料。传统配位聚合物框架材料电导率低,因此,如何设计并合成具有一定导电性的配位聚合物框架材料,满足能源及其相关领域对于材料电学性质的要求,成为配位聚合物框架材料领域的研究热点方向之一。本综述介绍了近年来导电二维配位聚合物框架材料的设计思路及电导率测量方法,并对这类材料的制备及其在能源转化及存储方面的应用进行了总结。最后,对二维高导电配位聚合物今后的研究和发展方向进行了展望。     

苏云金芽孢杆菌杀虫基因导入中国栽培水稻品种中花11号获得转基因植株

在水稻的遗传转化中,迄今尚未见到将优良性状基因导入生产推广品种并获得转基因植株的报道。我们首次将B.t.杀虫基因导入到生产推广品种中花11号中,并建立了一套转导外源DNA的有效方法。应用剪掉内颖,同时去掉柱头保留完整外颖的方法可使种子结实率提高到50％。遗传转化植株经分子杂交实验室证实,B.t.杀虫基因已整合到水稻基因组中,得到了转杀虫基因水稻工程植株。用Jefferson的组织化学法测定转基因植株的β-glucuronidase的活性,与B.t.杀虫基因形成翻译融合的GUS基因得到了表达,这为B.t.杀虫基因在转基因水稻植株中的表达提供了证据。     

甲醇／丙烷在ZSM—5分子筛上偶合转化过程的研究

考察了甲醇／低碳烷烃在ＺＳＭ－５分子筛上偶合转化为芳烃和低碳烯烃的反应过程。对特定的催化体系，存在一最佳原料配比，使反应的热效应近似为零。偶合转化时甲醇完全转化，低碳烷烃的转化率低；不同催化剂上偶合转化产物分布差别极大，与ＨＺＳＭ－５相比，Ｇａ改性后可获得较高的芳烃和低碳烯烃收率。     

(R)-2-羟基-4-苯基丁酸乙酯的合成

综述了血管紧张素转化酶抑制剂类治疗高血压和充血性心力衰竭药物的关键中间体（R）－2－羟基－4－苯基丁酸乙酯的合成方法。参考文献25篇。     

离子液体介导CO2化学转化研究进展

The efficient utilization of carbon dioxide (CO₂) as a C1 feedstock is of great significance for green and sustainable development. Therefore, the efficient chemical conversion of CO₂ into value-added products has recently attracted a lot of research attention in recent years. The transformation of CO₂ generally requires high-energy substrates, specific catalysts, and harsh reaction conditions due to its high thermodynamic stability and kinetic inertness. Consequently, several efforts have been dedicated toward the development of high-performance catalysts and new reaction routes for CO₂ conversion over the last few decades. To date, many routes of convert CO₂ into value-added chemicals have been proposed, together with the development of heterogeneous and homogeneous catalysts. Among the advanced catalysts reported to date, ionic liquids (ILs) have been widely investigated and show great potential for the efficient, selective, and economical conversion of CO₂ into highly valuable products under mild conditions, even under ambient conditions. Some task-specific ILs have been designed with unique functional groups (e.g., —OH, —SO₃H, —NH₂, —COOH, and —C≡N), which can act as the solvent, absorbent, activating agent, catalyst, or cocatalyst to realize the transformation of CO₂ under metal-free and mild conditions. In addition, a variety of catalytic systems composed of ILs and metal catalysts have also been reported for the transformation of CO₂, in which the combination of the IL and metal catalyst is responsible for CO₂ conversion with high efficiency. In this review article, we summarize the recent advances in IL-mediated CO₂ transformation into chemicals prepared via C—O, C—N, C—S, C—H, and C—C bond forming processes. ILs that can chemically capture CO₂ with high capacity are first introduced, which can activate CO₂ via the formation of IL-based carbonates or carbamates, thus realizing the transformation of CO₂ under metal-free and mild conditions. Recent progress in IL-mediated CO₂ transformations to form carbonates and various kinds of N- and S-containing compounds (e.g., oxazolidinones, ureas, benzimidazolones, formamides, methylamines, benzothiazoles, and other chemicals) as well as CO₂ hydrogenation to give formic acid, methane, acetic acid, low-carbon alcohols, and hydrocarbons has been summarized in this review with a focus on the reaction routes, catalytic systems, and reaction mechanism. In these reactions, ILs can simultaneously activate the substrate via strong H-bonding in addition to activating CO₂, and the cooperative effects among the ionic and molecular species and metal catalysts accomplish the reactions of CO₂ with various kinds of substrates to afford a wide range of value-added chemicals. Finally, the shortcomings and perspectives of ILs are discussed. In short, IL-mediated CO₂ transformations provide green and effective routes for the synthesis of high-value chemicals, which may have great potential for a wide range of applications.     

Reactions in a Mixture of CH4 and CO2 under the Aciton of Microwave Discharge at Atmospheric Pressure

Reactions between CH4 and CO2 under the action of continuous microwave discharge at atmospheric pressure were studied in a special homemade reactor,The main products were CO and H2,while acetylene and ethylene were also found in the products.Experimental results show that conversions of CH4 and CO2 could be higher than 90% without the presence of any catalyst,Effects of CO2/CH4 molar ratio and total flow rate of the feed gas on the reaction were also investigated.