具有生物活性的有机硅化合物的研究 Ⅴ. N-烃基-N-三甲(三乙氧)硅基-2-呋喃甲酰胺类化合物的合成及生物活性研究

目前生物有机硅化学已经形成了有机硅化学的一个新的研究领域,已发现大批具有较高和某些专门的生物活性的有机硅化合物。我们对一些酰氧基类型有机硅化合物的毒性进行了研究,总结了毒性和结构关系,发现其毒性一般都比相应的不含硅的母体化合物低;研究了某些有机硅的取代苯氧乙酸酯的生物活性及水杨酰替苯胺类型的有机硅化合物。本文合成了一系列新的2-呋喃甲酰胺类型的有机硅化合物,研究了它们对一些植物病原菌的抗菌活性,探讨了其结构与抗菌活性的关系.     

有机硅化合物和有机硼化合物在有机半导体材料中的应用

有机硅化合物和有机硼化合物是有机化学中2类非常重要的化合物,它们在有机合成化学和材料化学等领域都有着广泛的应用。有机半导体材料是一个新兴的研究领域,这2类化合物在这个新兴领域中也有着独特的贡献。简单介绍了有机硅化合物和有机硼化合物在有机半导体材料中的应用。     

硅亲电试剂参与碳硅交叉偶联反应研究进展

有机硅化合物因其特殊的性质而广泛应用于合成化学、材料、药物和农药化学等领域.有机硅化合物通常由亲核取代、烯烃硅氢化和碳氢键直接硅化等方法制备.近年来,通过交叉偶联构建碳硅键合成有机硅烷取得突破性进展,引起合成化学领域研究者的广泛关注和兴趣,成为有机硅化合物合成研究热点.主要从硅亲电试剂参与的Heck反应、Negishi...     

有机硅金属试剂在碳硅交叉偶联应用研究进展

有机硅化合物因其特殊的性质广泛应用于合成化学、医药、农药和材料等领域.有机硅化合物通常由亲核取代、烯烃硅氢化和碳氢键直接硅化等方法制备.近年来,交叉偶联构建碳硅键,特别是构建C(sp~3)—Si键取得突破性进展,引起广泛关注和兴趣,成为有机硅化合物合成研究热点.从极性反转的硅亲核试剂即有机硅金属试剂角度,总结近些年来有机硅金属试剂参与交叉偶联合成有机硅烷研究进展.有机硅硼试剂、有机硅镁试剂、有机硅锌试剂、联硅试剂、有机硅铝试剂和有机硅锂试剂等六方面总结各类金属试剂在碳硅键偶联的进展.     

铜催化不饱和化合物硅加成反应的研究进展

有机硅化合物不仅是十分有用的功能分子,而且是非常重要的有机合成中间体,在一定条件下通过适当的化学方法,可以转化为很多其它有用的功能性化合物.到目前为止,已经陆续发展了各种过渡金属参与的催化方法来制备有机硅化合物,其中铜催化不饱和化合物的硅加成反应是一种重要的合成有机硅化合物的方法.从不饱和化合物的种类出发,主要涉及α,β-不饱和化合物、亚胺、Morita-Baylis-Hillman(MBH)醇类化合物、对苯醌甲基化合物、α,β-不饱和炔羰化合物以及α,β-不饱和砜类化合物,综述了近几年在铜催化作用下这些不饱和化合物通过硅加成反应合成有机硅化合物的最新研究进展,有利于加深对铜催化硅加成反应的理解.     

B(C6F5)3催化不饱和烃的硅化反应

有机硅化合物由于其独特的性质,在合成化学、药物化学、高分子化学和有机光电材料等领域具有广泛的应用.不饱和化合物的硅化反应是获得有机硅化合物的重要途径之一,因此引起了化学家的关注并取得了令人瞩目的进展.B(C₆F₅)₃作为一类独特的非金属路易斯酸,近年来,其催化不饱和烃的硅化取得了重要的研究进展,详细介绍了不饱和烃的硅化反应及机理研究.     

利用点击化学制备有机硅材料及应用

有机硅材料因其特殊结构和性能已成为材料科学研究领域的热点之一,点击化学以其反应条件温和、高效、易于进行且无副产物和高产率等优点受到化学家的广泛关注.本文综述了近年来点击化学在有机硅材料合成中的研究成果,重点介绍了利用点击化学对有机硅化合物的功能化,有机硅两亲性聚合物及有机硅弹性体的合成及在生物医学和光电材料等方面的应用,并对点击化学在新型材料领域中的应用及其发展方向进行了展望.     

可见光促进有机硅化合物参与的化学转化

有机硅化合物具有重要用途,被广泛应用于材料科学与药物化学等领域.因此,有机硅试剂参与的化学转化一直倍受关注.近年来,可见光催化迅速发展,为有机合成化学提供了新的机遇.在光氧化还原体系下,有机硅试剂可以经由氢原子转移(Hydrogen atom transfer,HAT)或单电子转移(Single electron transfer,SET)过程转化为硅自由基或碳自由基进行反应,具有条件温和、选择性好和原子经济性高等优势.根据反应类型不同,主要综述了有机硅试剂作为硅自由基前体参与的烯(炔)烃硅氢化反应、烯(炔)烃双官能化反应、氮杂芳烃的硅基化反应,以及有机硅化合物作为碳自由基前体参与的亲核加成反应、Minisci反应、均裂取代反应和过渡金属介导的交叉偶联反应.     

1-烃基-1-硅杂环丁烷的合成及其Si—H键伸缩振动频率与结构关系的研究

硅杂环丁烷在有机硅化学中是一类非常重要的小分子环系化合物。由于硅杂环丁烷和环丁烷的环张力相似,因而显示出较高的反应活性。例如能与某些试剂作用,生成开环产物;在光解或热解条件下,产生具有Si=C结构的高活性中间体,可用以合成多种有机硅化合物。     

有机硅合成新方法

有机硅材料作为一类具有独特优异性能的新材料,已成为化学和材料领域的重点研究方向之一。本文综述了近年来国内外有机硅合成的新方法,主要包括炔基-叠氮环加成反应、巯基-双键反应和胺-烯迈克尔加成反应等,重点介绍各种合成方法的优势及在制备新型功能化的有机硅化合物、有机硅聚合物及有机硅弹性体等中的应用,并对未来有机硅合成方法的发展方向进行了展望。     

A novel insight into the inductive effect in silicon chemistry

A revision of quantitative literature data for the reactivity of organosilicon compounds in light of conceptions stemmed from organic chemistry has been carried out. It has been found that in structure-reactivity analysis for organosilicon compounds, differently of carbon compounds, the inductive effect of substituents, at least in nucleophilic displacement reactions at silicon, must be expressed by two terms involving that for electronegativity. A protocol for the correlation analysis in organosilicon chemistry is now available.     

Structure-reactivity relationships in organosilicon chemistry revisited

Available quantitative data of the reactivity of organosilicon compounds were subjected to correlation analysis. As an alternative to the carbon chemistry values, the scale of steric constants E _S (Si) can be used for organosilicon compounds and the inductive effect is best expressed by two terms, involving the parameter of electronegativity of substituents. Alkyl substituents contribute to the reactivity exclusively through their steric effects, steric and polar effects in silicon compounds are additive and the resonance effect is insignificant. The correlation analysis can be employed in investigations of organosilicon reactions along with other methods.      

环硅氮烷的合成与应用研究进展(1)——环二硅氮烷

环二硅氮烷是有机硅氮化合物中结构与性能比较特殊的一类化合物,在材料化学及配位化学领域有重要的潜在应用前景.综述了近年来环二硅氮烷的合成方法与应用研究进展.在合成方面,主要分为3条路线,分别由环三硅氮烷锂盐、取代硅胺及六氯化二硅为起始物.在应用领域,介绍了环二硅氮烷的离子开环聚合、等离子聚合、与其它单体的共聚、水解和金属配合物的制备及其在陶瓷、粘合剂和预想的催化剂上的应用.     

Comparative study of the biological activity of organosilicon and organogermanium compounds

The literature data and the results of our own investigations on the comparative study of the biological activity of isostructural organogermanium and organosilicon compounds have been summarized. It has been shown that the series of organogermanium and organosilicon compounds is more active than the carbon analogues, the majority of organogermanium compounds are less toxic than the sila analogues, the biological activity of the compounds under study appears to be similar but can dramatically differ in the degree of activity, and, moreover, in some particular cases sila and germa analogues exhibit the opposite biological effects.     

杂环型稳定硅烯插入HF、H_2O和NH_3反应

硅烯为卡宾的硅类似物,在有机光和热化学中作为一类重要的反应活性中间体引起了化学界的广泛兴趣.杂环型硅烯是实验合成的稳定硅烯,因其在有机硅化学中的重要作用,十几年来在实验和理论上均有研究报道.本文基于单重态杂环型硅烯的特殊电子性质和丰富的化学反应性,系统探讨了几种杂环型硅烯的插入反应.使用密度泛函理论(DFT),在B3LYP/6-311++G(d,p)水平上研究了三种氮杂环型不饱和硅烯(1,3,4)和两种氮杂环型饱和硅烯(2,5)分别与H—X(X=F,OH,NH2)键的插入反应,阐明了插入反应的机理并对各反应的结果进行了比较.杂环型硅烯与H—X的插入反应机理类似于简单硅烯,体现了硅烯的亲电亲核的双重反应性.由反应势垒和反应热看,五种硅烯与H—X键的插入反应均为HF最容易,H2O次之,NH3最难.饱和硅烯的反应性比不饱和硅烯的反应活性高,这也间接验证了杂环型饱和硅烯在实验中较难合成.     

硅杂四元环化合物的合成和反应

硅杂四元环化合物在有机硅化学中是一类非常重要的小分子环系化合物, 广泛应用于有机化学、金属有机化学以及材料化学. 环上只含有一个硅原子的硅杂环丁烷可以通过γ-卤代丙基硅烷的Grignard反应、Si＝C键与烯烃的 [2＋2]环加成反应以及硅杂环丙烷的扩环反应合成, 环上只含有一个硅原子的硅杂环丁烯可以通过格氏试剂或锂试剂参与的Si—C键的关环反应、硅杂环丁烷的转化反应、硅卡宾对C—H键的插入反应、Si＝C键与炔烃的[2＋2]环加成反应以及二炔基硅烷的分子内成环反应等途径合成. 硅杂环丁烷和硅杂环丁烯由于存在环张力和具有一定的Lewis酸性, 能够通过扩环反应生成五元和六元含硅杂环化合物, 也能够通过开环反应生成不同结构的有机硅分子和聚合物, 抑或实现有机反应在温和条件下的转化.     

Chemistry of phenols: Recent advances in the chemistry of 2,3-dihydroxynaphthalene and the related analogues

This review describes the chemistry of 2,3-dihydroxynaphthalene and the related analogues. The synthetic routes reported to obtain the investigated structures are discussed. In addition, the reactivity and the synthesis of fused heterocyclic systems containing one or two heteroatoms are discussed. The compounds derived from 2,3-dihydroxynaphthalene are located in the basic skeleton of several natural drugs. The products were applied in the fields of polymer chemistry, physical chemistry, and medicinal chemistry. The different sections cover: methods of preparation, reactions, heterocyclic systems, macrocycles, organosilicon derivatives, coordination chemistry, and biological importance. The assessment relates to the recent reports and contains a short, targeted survey of the title compound for the past 15 years.     

Heterophase polymerization of styrene in the presence of organosilicon compounds of various natures

The heterophase polymerization of styrene has been carried out in the presence of surfactants—organosilicon compounds with different solubilities in aqueous and styrene phases and surface activities at the interface. It has been demonstrated that the stability of polymer suspensions prepared with water-insoluble organosilicon compounds is much higher than that in the presence of organosilicon surfactants soluble in organic and aqueous phases. In the former case, suspensions with narrower particle-size distributions are produced. The stability of polymer microspheres prepared at various monomer-to-water volume ratios has been tested. An increase in the monomer concentration above 25 vol % leads to the loss of system stability.     

Organosilicon compounds in supercritical carbon dioxide: Synthesis,polymerization, modification,and production of new materials

The main promising opportunities for the advantageous combination of organosilicon compounds and supercritical carbon dioxide both as a solvent and as a reagent in chemical processes are analyzed. The main processes of polymerization and modification of polymer matrices that are performed in supercritical СО₂ with the use of organosilicon materials of various types are outlined. Methods for the obtaining organosilicon polymers and polymer-inorganic composites and methods for the application of siloxane stabilizers in the dispersion polymerization of monomers in supercritical СО₂ are described. Studies of the insertion of a СО₂ molecule into Si–H, Si–N, and Si–O–Me bonds in reactions that feature exceptionally high chemical selectivity and afford a wide spectrum of products potentially useful for application in the chemistry of polymer materials are considered. It is shown that the silylation of surfaces of various types and morphologies in the medium of supercritical СО₂ is a rapidly developing green approach that makes it possible to obtain highly uniform defect-free coatings with variable desired functionality.     

Silylenes,Silenes, and Disilenes: Novel Silicon‐Based Reagents for Organic Synthesis?

Silylenes, silenes, and disilenes are silicon analogues of carbenes and alkenes. Since the first detection and isolation of these species a few decades ago, focus has been given to their fundamental structure and reactivity properties. Recent developments show that the time is set to exploit their unique chemistry in applied areas. Emerging applications in catalysis and stereoselective synthesis point to a new field within synthetic organosilicon chemistry.