手性膦配体的合成及其在不对称催化反应中的应用研究进展

手性膦配体的合成及其在不对称催化反应中的应用一直是不对称有机合成和催 化研究中非常重要的研究领域，大量的单齿、双齿和多齿磷配体被合成出来并成功 地应用于不对称催化研究。综述了近十几年来手性磷配体的研究进展。     

Chiral Iminophosphoranes—An Emerging Class of Superbase Organocatalysts

Chiral Brønsted base catalysis is a fascinating and highly explored field of research. For many years catalysts based on chincona alkaloid chiral scaffolds have constituted privileged systems widely employed in numerous base‐promoted organic transformations. Recently, a novel group of chiral base catalysts has been successfully introduced. The application of organosuperbases, namely cyclopropenimines, guanidines, and iminophosphoranes, as chiral catalysts is receiving increasing attention. The aim of this Concept article is to summarize recent progress in the field of chiral iminophosphorane superbase organocatalysis. Catalysts design, different approaches to their synthesis, and applications in asymmetric synthesis are outlined and discussed in detail.     

Vanadium in Asymmetric Synthesis: Emerging Concepts in Catalyst Design and Applications

In recent years vanadium catalysis has been extended to a range of different and even complementary directions in asymmetric synthesis. Inspired by nature’s way to activate both substrate and reagent in many cases, the design of efficient bifunctional and dinuclear vanadium catalysts has been achieved. Furthermore, vanadium catalysis has been an early field in which “hybrid catalysts” have been studied in detail by incorporation of oxovanadium complexes into proteins, thus giving artificial enzymes. In addition, a high compatibility of vanadium with proteins enabled the use of vanadium chemocatalysts for combinations with enzyme catalysis in one‐pot, thus leading to dynamic kinetic resolutions. In this contribution, these three concepts of vanadium catalysis opening up new perspectives for asymmetric synthesis are reviewed.     

手性有机小分子催化的最新进展*

手性有机小分子催化是近年来不对称催化领域发展起来的一个研究热点。手性有机小分子催化具有反应条件温和,环境友好,催化剂易于回收利用等优点,符合绿色化学的要求。本文根据手性有机催化剂活化模式的不同,从烯胺催化、亚胺催化、氢键活化、卡宾催化、相转移催化以及光化学等方面对近年来的有机小分子催化的进展,特别是中国学者的工作做一简要评述。重点通过对不同催化体系下催化剂和反应底物之间立体效应和电子效应的考察,发现控制反应立体选择性以及活化惰性底物的规律,进而设计更加高效的手性有机小分子催化剂,完善和拓展有机小分子催化的不对称合成。     

Hydrides,Amides and Imides Mediated Ammonia Synthesis and Decomposition

Ammonia is feeding nearly half the world population and also holds the promise as a carbon‐free energy carrier. The development of ammonia synthesis and decomposition processes under milder conditions is a grand challenge for more than a century. Increasing effort is devoted to this area in recent years and encouraging progress has been achieved. In this paper, we summarize our recent research using alkali or alkaline earth metal amides, imides and hydrides for ammonia synthesis and decomposition. These materials could serve as either indispensible component of active center in thermal catalytic process or nitrogen carrier for chemical looping ammonia synthesis. The synergy of amide, imide, or hydride with transition metals enables ammonia synthesis or decomposition with unprecedented high efficiency under milder reaction conditions, and thus opens an avenue to advance the chemistry or catalysis of N₂ fixation reaction. The compositional and structural diversity of the amide, imide and hydride materials provides plenty of opportunity and potential for further exploration and optimization.     

Homochiral Covalent Organic Frameworks for Asymmetric Catalysis

Owing to their permanent porosity, highly ordered and extended structure, good chemical stability, and tunability, covalent organic frameworks (COFs) have emerged as a new type of organic materials that can offer various applications in different fields. Benefiting from the huge database of organic reactions, the required functionality of COFs can be readily achieved by modification of the corresponding organic functional groups on either polymerizable monomers or established COF frameworks. This striking feature allows homochiral covalent organic frameworks (HCCOFs) to be reasonably designed and synthesized, as well as their use as a unique platform to fabricate asymmetric catalysts. This contribution provides an overview of new progress in HCCOF-based asymmetric catalysis, including design, synthesis, and their application in asymmetric organic synthesis. Moreover, major challenges and developing trends in this field are also discussed. It is anticipated that this review article will provide some new insights into HCCOFs for heterogeneous asymmetric catalysis and help to encourage further contributions in this young but promising field.     

纳米碳材料非金属催化的研究进展

纳米碳材料直接作为催化剂的非金属碳催化是目前材料科学与催化领域的前沿方向之一.相对于传统金属催化剂,纳米碳材料催化剂具有高效环保、低能耗、耐腐蚀等优点.在烃类转化、化学品合成、能源催化等领域表现出优异的催化性能和发展潜力.综述了近年来纳米碳非金属催化研究的最新进展,主要包括新型纳米碳材料的表面性质、催化特性、反应机理和宏观制备等关键问题,并对纳米碳催化存在的挑战和前景进行了展望.     

The cycloaddition reaction using visible light photoredox catalysis

In recent years, visible light photoredox catalysis has emerged as an important research area in synthesis. In this review, we describe the recent progress in the visible light induced cycloaddition reactions, including [2+2], [3+2], [4+2] and [2+2+2] cycloadditions, for the construction of four-, five- or six-membered cycles and polycycles. Furthermore, the mechanisms for these transformations are also discussed, in which the formation of the radicals is initiated by a visible light photoredox catalysis process.     

DNA‐Based Hybrid Catalysts for Asymmetric Organic Synthesis

Stereoselective hybrid systems based on metal‐assisted catalysis with a chiral biomacromolecule form an attractive research area for the synthesis of enantiomerically pure compounds. Although various methods are available for this purpose, most rely on the use of enzymes, proteins, or RNA. The application of DNA‐based hybrid catalysts for enantioselective synthesis emerged only a few years ago. DNA‐based hybrid catalysts have been self‐assembled from DNA and a metal complex with a specific ligand through supramolecular or covalent anchoring strategies and have demonstrated high stereoselectivity and rate enhancement in Lewis acid catalyzed reactions, such as Diels–Alder, Michael addition, and Friedel–Crafts reactions. For these reactions, cheap and commercially available salmon testes DNA has generally been used. In this Minireview, we summarize recent developments in the area of asymmetric catalysis with DNA‐based hybrid catalysts.     

α-氨基酸的不对称合成新进展

α-氨基酸的不对称合成是不对称合成方法学中不可缺少的重要组成部分. 着重从不对称反应形成化学键的角度出发, 综述了α-氨基酸不对称合成的最新进展.     

葫环联脲新进展

葫环联脲这类新型主体分子正受到化学家们的广泛关注,并逐渐成为超分子化学研究领域中的一个热点.本文综述了近两-来葫环联脲同系物、衍生物的合成及其在分子识别、分子催化、分子组装等方面的研究进展,并对该领域的研究前景作一展望.     

高效手性膦配体的合成及应用

较为详细地综述了高效、应用广泛的手性膦配体的合成进展，并介绍了其在不对称催化反应中的应用。参考文献49篇。     

Supramolecular Coordination Cages for Asymmetric Catalysis

Inspired by the high efficiency and specificity of enzymes in living systems, the development of artificial catalysts intrinsic to the key features of enzyme has emerged as an active field. Recent advances in supramolecular chemistry have shown that supramolecular coordination cages, built from non-covalent coordination bonds, offer a diverse platform for enzyme mimics. Their inherent confined cavity, analogous to the binding pocket of an enzyme, and the facile tunability of building blocks are essential for substrate recognition, transition-state stabilization, and product release. In particular, the combination of chirality with supramolecular coordination cages will undoubtedly create an asymmetric microenvironment for promoting enantioselective transformation, thus providing not only a way to make synthetically useful asymmetric catalysts, but also a model to gain a better understanding for the fundamental principles of enzymatic catalysis in a chiral environment. The focus here is on recent progress of supramolecular coordination cages for asymmetric catalysis, and based on how supramolecular coordination cages function as reaction vessels, three approaches have been demonstrated. The aim of this review is to offer researchers general guidance and insight into the rational design of sophisticated cage containers for asymmetric catalysis.     

有机催化不对称Michael/环化串联反应的研究进展北大核心CSCD

串联反应能够减少反应步骤、简化操作、降低成本、实现高效率转化,符合原子经济性和绿色化学理念.特别是有机催化的不对称串联环化反应以一锅法连续催化多个化学反应,为高效合成多手性中心环状结构提供了新方法.不对称Michael/环化串联反应是构建光学活性状化合物的常用方法之一,近些年,各种有机小分子催化剂应用于不对称Michael/环化串联反应的报道不断增加,并且取得了重大进展.我们根据不同的催化剂类型综述了近5年来关于不对称Michael/环化串联反应的研究进展,并对有机催化不对称Michael/环化串联反应的发展趋势进行了展望.     

From nanographene and graphene nanoribbons to graphene sheets: chemical synthesis

Graphene, an individual two-dimensional, atomically thick sheet of graphite composed of a hexagonal network of sp(2) carbon atoms, has been intensively investigated since its first isolation in 2004, which was based on repeated peeling of highly oriented pyrolyzed graphite (HOPG). The extraordinary electronic, thermal, and mechanical properties of graphene make it a promising candidate for practical applications in electronics, sensing, catalysis, energy storage, conversion, etc. Both the theoretical and experimental studies proved that the properties of graphene are mainly dependent on their geometric structures. Precise control over graphene synthesis is therefore crucial for probing their fundamental physical properties and introduction in promising applications. In this Minireview, we highlight the recent progress that has led to the successful chemical synthesis of graphene with a range of different sizes and chemical compositions based on both top-down and bottom-up strategies.     

多策略可控合成原子精度合金纳米团簇

合金纳米团簇作为一类新兴的多功能纳米材料已被广泛用于催化、光学传感以及生物医学成像等研究领域,而纳米团簇的可控合成和结构特征是调节纳米团簇性质并对其进一步利用的基础。尽管当前有关金属纳米团簇可控合成和结构特征的研究主要集中在单金属纳米团簇中,但有关合金纳米团簇原子精度的可控合成也取得了显著的进展。本文综述了配体保护的合金金属纳米团簇原子精度可控合成策略,包括一步合成法、金属交换、配体交换、化学刻蚀、簇间反应、原位两相配体交换以及最新的表面模体交换反应,并对相关合成策略的优缺点进行了详细的讨论和阐述。     

Recent advances in water-mediated multiphase catalysis

Water is the most sustainable solvent, making it the obvious choice to replace organic solvents in various synthesis techniques. However, its applications in the chemical and pharmaceutical industries are often restricted by the low solubility of organic compounds in water. Essentially, the reactions of organic compounds in water are multiphase systems. Therefore, this review classifies aqueous-phase organic reactions into liquid–liquid, liquid–solid and gas–liquid–solid phase from the perspective of phase interfaces of multiphase reactions, and summarizes the research progress and breakthroughs in recent years, including the application of micellar catalysis, Pickering emulsion catalysis, micro-nanobubble/foam catalysis and “dry water” catalysis, as well as the unique advantages of using water as a medium. Finally, we point out the current challenges and future perspectives on multiphase catalysis in aqueous-phase reactions.     

模板剂在合成纳米材料中的应用与发展

模板法在纳米材料的合成过程中已成为一种非常重要的技术。利用其结构导向、骨架填充、平衡和匹配电荷等作用,可以达到精确地调控纳米材料孔道的大小、形状及结构的目的。本文主要对模板剂的种类进行了详细的分类,重点介绍了硬模板法和软模板法在合成纳米材料过程中的现状及特点,并具体介绍了模板剂在合成纳米生物材料及纳米催化剂、电化学、化工合成等方面的应用;阐述了模板法在介孔材料合成过程中的重要性,指出了目前模板剂方法存在的优缺点;提出了模板剂在超分子功能材料、光化学反应及催化工业等方面应用的纳米材料合成中的发展趋势和良好前景。     

Recent Developments in Asymmetric Phase‐Transfer Reactions

Phase‐transfer catalysis has been recognized as a powerful method for establishing practical protocols for organic synthesis, because it offers several advantages, such as operational simplicity, mild reaction conditions, suitability for large‐scale synthesis, and the environmentally benign nature of the reaction system. Since the pioneering studies on highly enantioselective alkylations promoted by chiral phase‐transfer catalysts, this research field has served as an attractive area for the pursuit of “green” sustainable chemistry. A wide variety of asymmetric transformations catalyzed by chiral onium salts and crown ethers have been developed for the synthesis of valuable organic compounds in the past several decades, especially in recent years.     

分子印迹模拟酶的制备与应用研究

分子印迹模拟酶是应用分子印迹技术合成的对目标分子具有特异性催化活性的聚合物,具有良好的化学和物理稳定性、结构预定性以及实用性。本文主要介绍了分子印迹模拟酶的构建策略,包括印迹过渡态类似物、印迹底物或底物类似物和其他构建途径;探讨了分子印迹模拟酶的制备方法,总结了分子印迹模拟酶在催化反应方面的应用,涉及有机合成催化、食品安全危害物分解、环境污染物降解和临床医学检验等。