Phosphoramidites: Privileged Ligands in Asymmetric Catalysis

Asymmetric catalysis with transition‐metal complexes is the basis for a vast array of stereoselective transformations and has changed the face of modern synthetic chemistry. Key to this success has been the design of chiral ligands to control the regio‐, diastereo‐, and enantioselectivity. Phosphoramidites have emerged as a highly versatile and readily accessible class of chiral ligands. Their modular structure enables the formation of ligand libraries and easy fine‐tuning for a specific catalytic reaction. Phosphoramidites frequently show exceptional levels of stereocontrol, and their monodentate nature is essential in combinatorial catalysis, where a ligand‐mixture approach is used. In this Review, recent developments in asymmetric catalysis with phosphoramidites used as ligands are discussed, with a focus on the formation of carbon–carbon and carbon–heteroatom bonds.     

Combinatorial Chemistry—Challenge and Chance for the Development of New Catalysts and Materials

One should not underestimate the capability of the combinatorial method in solid-state chemistry; this is the opinion of the author. Combinatorial chemistry can provide a large number of new compounds, but once the components that are interesting for a certain application have been successfully selected, the techniques of conventional catalysis and materials research are required. The strengths of conventional chemistry lie in the optimization, systematic modification, and improvement of new lead structures. In contrast, discovery is the potential strength of combinatorial chemistry. Careful design is most important for the synthesis of useful libraries, since the diversity of the periodic table is much too large to be accessed comprehensively or systematically by such large libraries.     

Asymmetric Catalytic Aminoalkylations: New Powerful Methods for the Enantioselective Synthesis of Amino Acid Derivatives,Mannich Bases,and Homoallylic Amines

Modern methodologies such as the design of chiral catalysts using combinatorial techniques play a key role in the development of asymmetric aminoalkylations. Thus, powerful enantioselective syntheses for many attractive target compounds using chiral Lewis acid or base catalysts like 1 or 2 were created.     

Recent Advances in Covalent Organic Frameworks for Catalysis

Covalent organic frameworks (COFs) as an emerging type of crystalline porous materials, have obtained considerable attention recently. They have exhibited diverse structure and attractive performance in various catalytic reactions. It is highly expected to have a systematic and comprehensive review summing up COFs‐derived catalysts in homogeneous and heterogeneous catalysis, which is favorable to the judicious design of an efficient catalyst for targeted reaction. Herein, we focus on summarizing recent and significant developments in COFs materials, with an emphasis on both the synthetic strategies and targeted functionalization, and categorize it in accordance with the different types of catalytic reactions. Their potential catalysis applications are reviewed thoroughly. Moreover, a personal view about the future development of COFs catalysts with respect to the large‐scale production is also discussed.     

Combinatorial chemistry approach to chiral catalyst engineering and screening: rational design and serendipity

An efficient asymmetric catalyst relies on the successful combination of a large number of interrelated variables, including rational design, intuition, persistence, and good fortune-not all of which are necessarily well-understood; this renders such practice largely empirical. As a result, the possibility of using combinatorial chemistry methods in asymmetric catalysis research has been widely recognized to be highly desirable. In this account, we attempt to show the principle and application of combinatorial approach in the discovery of chiral catalysts for enantioselective reactions. The concept focuses on the strategy for the creation of a modular chiral catalyst library by two-component ligand modification of metal ions on the basis of molecular recognition and assembly. The self-assembled chiral catalyst with two different ligands indeed exhibited synergistic effects in terms of both enantioselectivity and activity in comparison with its corresponding homocombinations in many reactions. The examples described in this paper demonstrated the powerfulness of combinatorial approach for the discovery of novel chiral catalyst systems, particularly for the development of highly efficient, enantioselective, and practical catalysts for enantioselective reactions. We hope this concept will stimulate further work on the discovery of more highly efficient and enantioselective catalysts, as well as unexpected classes of catalysts or catalytic enantioselective reactions in the future with the help of a combinatorial chemistry approach.     

无机合成与制备化学研究进展

本文从极端条件合成、软化学合成、特殊凝聚态和聚集态制备、形貌与尺寸修饰、缺陷与价态控制、组合化学合成、计算机辅助合成、理想合成与生物模拟合成等几个侧面, 阐述近年来无机合成与制备化学研究的进展。     

微波辅助组合合成的研究进展

微波辅助组合合成技术是近年来发展起来的一种新的制备化合物库的组合化学技术, 它不仅可以克服传统固相组合合成技术以及液相组合合成技术无法提高产物收率的不足, 而且利用该技术所制得的化合物库中对应的是高纯度的单一化合物, 采用高通量筛选技术可以快速直接地确定高活性结构, 极大地提高了新药开发的效率. 主要就近年来微波辅助组合合成技术的研究进展情况进行介绍, 内容包括固相组合合成、基于聚合物支载的催化剂的组合合成、液相组合合成、氟相组合合成以及组合平行合成等.     

固相合成及组合化学用的高聚物载体

综述了用于固相合成及组合化学的高聚物载体的制备方法、特征、应用和最新进展,重点介绍了目前广泛用作固相载体的交联聚苯乙烯树脂、聚酰胺树脂和TentaGel树脂,并对几类新型载体如聚乙二醇、聚四氢呋喃衍生物交联剂改性的聚苯乙烯树脂、非芳环体系的POEPOP,树脂和SPOCC树脂作了简要的概述。     

Suzuki反应中催化体系的研究进展

随着过渡金属催化的交叉偶联反应的出现,有机合成化学在20世纪的最后25年得到了快速的发展,并且这些反应的重要性被普遍认可.其中,Suzuki偶联反应因其多功能性、兼容性和对包括材料科学和药物合成在内的多种学科的关键贡献,而占据了更加特殊的地位.尽管到2010年为止Suzuki反应已取得重大进展,但随着可持续和绿色化学发展的需求,Suzuki反应的催化体系仍待进一步优化提高.这里概述的催化剂为C-C键的构建提供了方便和绿色的合成途径.在这篇综述中,我们总结了科研工作者对于Suzuki反应在改进催化剂制备策略、优化催化反应条件、提高催化剂重复利用性能和降低催化剂成本方面做的一系列研究.     

Nickel‐Catalyzed Reductive Cross‐Coupling of Aryl Halides with Monofluoroalkyl Halides for Late‐Stage Monofluoroalkylation

A combinatorial nickel‐catalyzed monofluoroalkylation of aryl halides with unactivated fluoroalkyl halides by reductive cross‐coupling has been developed. This method demonstrated high efficiency, mild conditions, and excellent functional‐group tolerance, thus enabling the late‐stage monofluoroalkylation of diverse drugs. The key to success was the combination of diverse readily available bidentate and monodentate pyridine‐type nitrogen ligands with nickel, which in situ generated a variety of readily tunable catalysts to promote fluoroalkylation with broad scope with respect to both coupling partners. This combinatorial catalysis strategy offers a solution for nickel‐catalyzed reductive cross‐coupling reactions and provides an efficient way to synthesize fluoroalkylated druglike molecules for drug discovery.     

Nitrogen Donor Protection for Atomically Precise Metal Nanoclusters

Surface organic ligands are critical in dictating the structures and properties of atomically precise metal nanoclusters. In contrast to the conventionally used thiolate, phosphine and alkynyl ligands, nitrogen donor ligands have not been used in the protection for well-defined metal nanoclusters until recently. This review focuses on recent developments in atomically precise metal nanoclusters stabilized by different types of nitrogen donor ligands, in which the synthesis, total structure determination and various properties are covered. We hope that this review will provide insights into the rational design of N donor-protected metal nanoclusters in terms of structural and functional modulation.     

A Photoactivated Cu–CeO2 Catalyst with Cu‐[O]‐Ce Active Species Designed through MOF Crystal Engineering

Fully utilizing solar energy for catalysis requires the integration of conversion mechanisms and therefore delicate design of catalyst structures and active species. Herein, a MOF crystal engineering method was developed to controllably synthesize a copper–ceria catalyst with well‐dispersed photoactive Cu‐[O]‐Ce species. Using the preferential oxidation of CO as a model reaction, the catalyst showed remarkably efficient and stable photoactivated catalysis, which found practical application in feed gas treatment for fuel cell gas supply. The coexistence of photochemistry and thermochemistry effects contributes to the high efficiency. Our results demonstrate a catalyst design approach with atomic or molecular precision and a combinatorial photoactivation strategy for solar energy conversion.     

Dinuclear Gold Catalysis: Are Two Gold Centers Better than One?

A common golden thread: The exact role of dinuclear gold species in catalysis has recently attracted considerable attention. Such well-defined complexes can now be isolated and fully characterized and may assist in elucidating the exact action of gold centers in gold-catalyzed reactions. In view of the latest developments in this area, possibilities now abound in terms of mechanistic exploration and novel catalyst design.     

组合化学法在筛选真空紫外荧光材料中的应用

综述了近年来组合化学法在筛选新型真空紫外荧光材料研究方面取得的进展, 包括组合材料库的并行合成和高通量表征技术, 并重点介绍了组合材料库的设计艺术, 最后列举了组合化学法筛选真空紫外荧光材料体系研究的实例及结果.     

Supramolecular approaches to generate libraries of chelating bidentate ligands for homogeneous catalysis

The process of catalyst discovery and development relying on combinatorial methods has suffered so far from the difficult access to structurally diverse and large libraries of ligands, in particular the structurally more complex class of bidentate ligands. A completely new approach to streamline the difficult ligand synthesis process is to use structurally less complex monodentate ligands that self-assemble in the coordination sphere of a metal center through noncovalent attractive ligand-ligand interactions to generate bidentate, chelating ligands. When complementary attractive ligand-ligand interactions are employed, it is even possible to generate libraries of defined chelate-ligand catalysts by simply mixing two different monomeric ligands. This Minireview summarizes the first approaches and results in this new field of combinatorial homogeneous catalysis.     

Combinatorial Chemistry in Heterogeneous Catalysis: A New Scientific Approach or “the King's New Clothes”?

The spectacular success in materials science of the application of combinatorial chemistry has raised the hope that it may eventually lead to a new scientific approach to catalyst development. This method is, within the constraints of heterogeneous catalysis, merely a potentially efficient tool to be used in rational catalyst development and should not be considered an independent novel strategy towards rational catalyst design.     

Combinatorial Approach to the Hydrothermal Synthesis of Zeolites

One hundred or more solid-state syntheses can be conducted in parallel and employed for the combinatorial hydrothermal syntheses of zeolites by using a novel multiautoclave design. The operation of the multiautoclave was ascertained by the reinvestigation of the complete Na₂O-Al₂O₃-SiO₂ ternary system in a single experiment. In the picture on the right, the shaded areas on the left show the crystallization fields of the different phases obtained.     

Directed Evolution of Enzymes

On the way to a combinatorial biotechnology? The directed evolution of enzymes promises a rapid access to effective biocatalysts. New molecular biology techniques for random mutagenesis in combination with high-throughput screening might revolutionize the creation of enzymes with new and improved properties.     

组合多相催化研究进展*

本文对组合多相催化研究进展进行了较全面的综述,介绍了组合多相催化过程、样品库制备、库表征-高通量筛选技术及相应的微型组合反应器,并讨论了组合多相催化技术的发展趋势.     

Asymmetric organocatalytic Biginelli reactions: a new approach to quickly access optically active 3,4-dihydropyrimidin-2-(1H)-ones

The Biginelli reaction, known for over 100 years, is an important multicomponent reaction for accessing dihydropyrimidinones (DHPMs). The individual enantiomers of DHPMs exhibit different or even opposite pharmaceutical activities, which require synthetic methods to easily access the optically pure DHPMs. In recent decades, many efforts have focused on developing procedures for the preparation of optically active Biginelli products. In this article, we will summarize the developments in the synthetic methods to access optically active DHPMs with an emphasis on the recent advances in the asymmetric catalytic Biginelli reactions, along with concepts to design the organocatalytic asymmetric variants.