聚合物负载纳米材料及其在催化领域的应用

纳米材料几何尺寸小、比表面积大,具有广阔的应用前景。 以聚合物负载纳米材料能抑制其聚集、提高稳定性,更好地实现其功能。 本文总结了聚合物负载纳米材料的制备方法,探讨了这些复合材料在催化领域中的应用,并对其发展趋势作了总结和展望。     

双金属纳米材料与催化

双金属纳米材料作为工业上少见的一类催化剂材料,在合成过程中可通过对其组成、结构晶粒大小尺寸的调控,实现其催化性能的合理调控,因此,近年来备受催化材料化学领域科技工作者的广泛关注.随着纳米材料调控合成方面的技术进步,具有均一小尺寸可控结构的纳米材料对于制备高效催化剂材料和研究催化反应机理具有重要的意义.结合纳米技术探索开发设计新型的双金属纳米催化剂材料颇具挑战性.本文围绕双金属纳米催化剂的合成、结构及其相关催化性能,从不同的双金属纳米催化剂出发,对催化剂的性能提高、催化机理研究的若干问题和分析手段及方法在催化研究中的进展发表一点初浅认识.     

过渡金属催化交叉偶联反应及其在液晶合成中的应用

过渡金属催化交叉偶联反应及其在液晶合成中的应用杜卫红安忠维徐茂梁（西安近代化学研究所西安７１００６１）关键词过渡金属催化交叉偶联反应合成液晶液晶是一类具有特殊物理性能的有机化合物，其分子结构要求长径比大于４，官能团包括芳（杂）环、脂环、烷基、双键、叁...     

环糊精衍生物在金属催化有机合成中的应用

综述了环糊精(包括α-环糊精,β-环糊精和γ-环糊精)衍生物在金属催化有机合成中的应用,主要包括其作为金属离子配体、金属纳米粒子稳定剂和反相相转移催化剂在氧化、水解、还原、偶联等金属催化反应中的应用.其中环糊精衍生物作为金属离子配体应用最广,由于环糊精部分与底物形成包结络合物,拉近了底物和具有催化活性的金属离子的距离,并固定了底物的反应部位,往往可以显著提高催化反应的反应速率,增强反应的区域选择性和对映选择性.     

功能高分子纳米材料的制备及其催化性能

将两种具有不同结构的共轭高分子聚糠醇鄄苯酚(PFP-0)及聚对苯撑(PPP-0)分别在一定条件下热活化处理后, 成功地用作为染料废水处理催化剂PFP及PPP; 利用DTA-TG、TEM、FT-IR、UV-Vis等技术对样品进行了表征. 结果表明, PFP及PPP在自然光照射及空气氧存在的温和条件下, 很短时间内就能使染料亚甲基蓝(MB)几乎完全脱色降解和大部分矿化; 材料共轭结构对其稳定性能有较大的影响; 横向比较分析发现, 极性基团的存在, 对材料的催化性能有重要影响.     

金属有机骨架HKUST-1及其衍生材料在催化中的应用进展

金属有机骨架材料(MOFs)作为异相催化剂受到了日益广泛的关注。在众多经典MOFs结构中,HKUST-1及其衍生材料是研究最多的类型之一。HKUST-1具有原料简单、易于合成、结构稳定、孔隙率高等多种优点,在异相催化领域中具有广阔的应用前景。已有多种HKUST-1相关材料被用作催化剂,包括HKUST-1本身、缺陷型结构、负载活性客体分子的复合型材料以及HKUST-1衍生的多孔碳纳米材料等。本文围绕HKUST-1作为催化剂的结构设计以及在不同催化反应中的应用展开总结与介绍,以期为相关MOFs材料的设计和催化研究提供一定参考。     

手性高分子金属络合物在不对称催化中的应用

综述了手性高分子金属络合物（人工合成）在不对称催化中的应用及最新进展,参考文献５３篇。     

溴代烯烃在金属催化偶联反应中的应用

溴代烯烃是一类重要的有机合成中间体,通过金属催化的偶联反应可以有效地形成碳-碳及碳-杂键.本文综述了溴代烯烃在金属催化偶联反应中应用的最新进展.     

金属有机框架衍生碳纳米材料的精准合成与应用进展

碳基材料因其比表面积大、热稳定性和化学稳定性好而被广泛应用于化工、能源、环保等领域。金属有机框架(MOFs)材料具有结构丰富、比表面积大、电导率理想和孔隙率可控的特点,已经成为碳基材料优良的前驱体。以MOFs为模板,通过合成工艺调控以及特定官能团、元素掺杂等方式修饰后获得的功能性碳纳米材料,保留MOFs的特殊结构的同时,还可以调整碳材料结构组成与形貌特点,改善碳材料结构有序性等,达到精准合成的目的。此外,杂原子(如N、 S和P等)的引入也能提升MOFs碳基材料的性能,使MOFs衍生碳具有更加广泛的应用潜力。本文综述了近年来以MOFs为前驱体,利用不同MOFs的特点精准合成特殊结构的碳纳米材料,并总结了其作为吸附剂、催化剂以及电极材料的应用进展。     

纳米材料催化发光分析研究进展

本文综述了近年纳米材料催化发光分析在快速检测、分析物区分及高通量筛选催化剂等方面的研究进展,并对其今后的发展方向进行了展望。     

Synthesis and bioanalytical applications of specific-shaped metallic nanostructures: A review

Many successful synthesis routes for producing different shapes of metallic nanostructures, including sphere, rod, cube, and hollow shapes, have been developed in the past few decades. Many applications using these nanostructures have been studied because the outstanding properties of the nanostructures are not exhibited by their bulk-state counterparts. This review paper reports some recent developments in clinical and biosensor applications. The first part focused on the synthesis methods of metallic nanostructures having various shapes along with their optical properties. The second and third part is an introduction of the gold nanoparticle assemblies and arrays, explaining the conjugation methods of metallic nanostructures with biological entities. The final part reviews on the recent bioanalytical applications using various shapes of metallic nanostructures.     

Non-enzyme entrapping biohydrogels in catalysis

This review provides an overview of the current status and future directions of the use of biohydrogels (i.e., hydrogels obtained from biopolymers) as heterogeneous catalysts and/or supports for catalytic metal nanoparticles. This review collects a wide variety of biohydrogels used in catalytic applications, including gels made of polysaccharides (chitosan, alginate, carrageenan, dextran, agarose), proteins (gelatin, silk fibroin, ferritin) and nucleic acids (DNA). Additionally, the most significant features about the recyclability of these materials, their structural properties and the type of reactions that they catalyze are discussed.     

2020 Roadmap on two-dimensional nanomaterials for environmental catalysis

Environmental catalysis has drawn a great deal of attention due to its clean ways to produce useful chemicals or carry out some chemical processes. Photocatalysis and electrocatalysis play important roles in these fields. They can decompose and remove organic pollutants from the aqueous environment, and prepare some fine chemicals. Moreover, they also can carry out some important reactions, such as O₂ reduction reaction (ORR), O₂ evolution reaction (OER), H₂ evolution reaction (HER), CO₂ reduction reaction (CO₂RR), and N₂ fixation (NRR). For catalytic reactions, it is the key to develop high-performance catalysts to meet the demand for targeted reactions. In recent years, two-dimensional (2D) materials have attracted great interest in environmental catalysis due to their unique layered structures, which offer us to make use of their electronic and structural characteristics. Great progress has been made so far, including graphene, black phosphorus, oxides, layered double hydroxides (LDHs), chalcogenides, bismuth-based layered compounds, MXenes, metal organic frameworks (MOFs), covalent organic frameworks (COFs), and others. This content drives us to invite many famous groups in these fields to write the roadmap on two-dimensional nanomaterials for environmental catalysis. We hope that this roadmap can give the useful guidance to researchers in future researches, and provide the research directions.     

2020 Roadmap on two-dimensional nanomaterials for environmental catalysis

This roadmap demonstrates a series of two-dimensional nanomaterials, such as graphene, black phosphorus, oxides, layered double hydroxides, chalcogenides, bismuth-based layered compounds, MXenes, metal organic frameworks, covalent organic frameworks, and others, for environmental catalysis.     

Understanding plasmonic catalysis with controlled nanomaterials based on catalytic and plasmonic metals

Recently, it has been established that the localized surface plasmon resonance (LSPR) excitation in plasmonic nanoparticles can be put toward the acceleration and control of molecular transformations. This field, named plasmonic catalysis, has emerged as a new frontier in nanocatalysis. For metals such as silver (Ag), gold (Au), and copper (Cu), the LSPR excitation can take place in the visible and near-infrared ranges, opening possibilities for the conversion of solar to chemical energy and new/alternative reaction pathways not accessible via conventional, thermally activated catalytic processes. As both catalytic and optical properties can be tuned by controlling several physical and chemical parameters at the nanoscale, design-controlled nanomaterials open the door to unlock the potential of plasmonic catalysis both in terms of fundamental understanding and optimization of performances. In this context, after introducing the fundamentals of plasmonic catalysis, we provide an overview on the current understanding of this field enabled by the utilization of designed-controlled nanostructures based on plasmonic and catalytic metals as model systems. We start by discussing trends in plasmonic catalytic performances and their correlation with nanoparticle size, shape, composition, and structure. Then, we highlight how multimetallic compositions and morphologies containing both catalytic and plasmonic components enables one to extend the use of plasmonic catalysis to metals that are important in catalysis but do not support LSPR excitation in the visible range. Finally, we focus on key challenges and perspectives that are critically important to assist us in designing future energy-efficient plasmonic-catalytic materials.     

Investigation of various synthetic protocols for self-assembled nanomaterials and their role in catalysis: progress and perspectives

Self-assembly is one of the most used strategies in the controlled synthesis and design of well-organized nanomaterials for various applications in diverse realms namely catalysis, sensors, microelectronics, energy storage, and energy conversion. It is quite common to see reports on the synthesis and design of several self-assembled nanomaterials for the application in the catalysis of various chemical, photochemical, and electrochemical reactions and processes. Nevertheless, a combined overview on the synthetic strategies for self-assembled nanomaterials has not been reported in any form in literature. Owing to the current interest shown and the future significance on the self-assembled nanomaterials, it is highly essential to have such an elaborated review on the progress and perspectives of synthesis of self-assembled nanomaterials and their subsequent application to catalysis of various chemical, photochemical, and electrochemical reactions and processes. In this review, we have highlighted various synthetic methodologies used so far for fabricating the self-assembled nanomaterials that includes Langmuir–Blodgett method, layer-by-layer assembly, amphiphilic (artificial and bio) self-assembly, and template-free approach. Nanomaterials derived from the above mentioned methods in various catalysis reactions are also highlighted in detail with an emphasis on confronts and prospects in the field of materials self-assembling and its concomitant application to catalysis.     

Bimetallic cluster complexes: synthesis, structures and applications to catalysis

A brief history of the seminal discoveries in the field of bimetallic cluster complexes with their structures is presented. A review of some recent studies of palladium and platinum-ruthenium cluster complexes is concluded with a discussion of applications of these complexes in the area of homogeneous hydrogenation catalysis of alkynes.     

Preparation of raspberry-like polypyrrole composites with applications in catalysis

Raspberry-like composites were prepared by coating the silver/polypyrrole core/shell composites onto the surface of silica spheres via oxidation polymerization of pyrrole monomer with [Ag(NH₃)₂]⁺ ions as oxidants. The whole process allowed the absence of stabilizers, which greatly improved the quality of the conducting polymer composites. The morphology of the resulting composites was investigated, which can be described as raspberry-like; also, the structure and composition of the composites were characterized in detail. A possible formation mechanism was proposed. The present synthetic strategy substantially extended the scope of metal/conducting polymer composite synthesis. The raspberry-like composites exhibited excellent catalytic properties in the reduction of methylene blue dye with the reducing agent of sodium borohydride.     

Impact of divalent metal cations on the catalysis of peptide bonds: a DFT study

Within the ATP-grasp family of enzymes, divalent alkaline earth metals are proposed to chelate terminal ATP phosphates and facilitate the formation of peptide bonds. Density functional theory methods are used to explore the impact of metal ions on peptide bond formation, providing an insight into experimental metal substitution studies. Calculations show that alkaline earth and transition metal cations coordinate with an acylphosphate reactant and aid in the separation of the phosphate leaving group. The critical biochemical reaction is proposed to proceed through the formation of a six-membered transition state in the relatively nonpolar active site of human glutathione synthetase, an ATP-grasp enzyme. While the identity of the metal ion has a moderate impact on the thermodynamics of peptide bond formation, kinetic differences are much sharper. Simulations indicate that several transition metal ions, most notably Cu²⁺, may be particularly advantageous for catalysis. The detailed mechanistic study serves to elucidate the vital role of coordination chemistry in the formation of peptide bonds.