含氟硼二吡咯单元金属有机骨架材料的研究进展

MOFs是一种具有高度有序孔道结构和较大比表面积的材料,而含氟硼二吡咯(BODIPY)发色团的MOFs材料是将BODIPY发色团设计成可与金属中心配位的配体并直接与金属离子配位或将该发色团作为光吸收天线引入到MOFs材料中所制备的材料,此类材料因对可见光有较强的吸收而受到广泛关注。本文总结了含BODIPY发色团MOFs材料的制备方法,探讨了此类材料的结构特点、光物理性质及应用前景,最后展望了未来此类材料的前景和发展趋势。本文可为BODIPY发色团的MOFs材料在光化学领域的发展提供参考。     

核壳结构金属-有机骨架及其衍生物在锂离子电池负极材料中的应用

金属–有机框架(MOFs)材料具有比表面积较大、孔径可调、制备容易、结构与功能多样性等优势,被广泛应用于电化学能源转化与储存领域。其中独特的核壳结构材料由于表面修饰的作用往往更能表现出核内与壳层的协同作用。本文介绍了具有核壳结构MOFs作为锂离子电池负极材料的发展现状,并重点综述其衍生物(多孔碳材料、金属氧化物、金属硫/硒化物以及金属/金属氧化物)的制备方法以及在锂离子电池负极中的应用。MOFs通过高温煅烧或改变化学反应条件的方法,可制备出结构可调的传统无机电极材料并表现出更优异的电化学性能。最后总结了核壳结构MOFs材料作为锂电负极材料存在的问题和挑战,并提出可能的解决途径和未来的应用前景。     

导电MOFs在能源转化中的应用

可再生能源供应方案包括析氢反应(HER)、析氧反应(OER)、氧还原反应(ORR)和二氧化碳还原反应(CO2RR)等多种反应,电催化剂对这些反应至关重要。到目前为止,已有一系列导电MOFs作为与能源相关电催化电极材料的报道。本文从提高MOFs导电能力和对产物的选择性、增强MOFs的化学稳定性及增加MOFs的反应活性位点等方面介绍了导电MOFs作为电催化剂的设计策略,重点综述了其在能源转化涉及的HER、OER、ORR以及CO2RR方面的应用,并从材料制备和应用需求角度出发, 对高性能导电MOFs材料在电催化领域所面临的挑战和前景进行了展望。     

MOFs在不饱和醛选择加氢中的应用研究进展

不饱和醛多相催化选择加氢制备不饱和醇常常被选作C=O键选择性加氢的代表性反应,长期以来一直备受关注,然而获得兼具高活性及高选择性的催化剂依然具有很大的挑战。近年来,由于金属有机骨架（Metal-organic frameworks MOFs）材料具有的独特性能,应用在加氢领域的研究越来越多,常用做催化剂载体或直接作为催化剂,以提高不饱和醇的收率。因此,本文综述了不同MOFs及其衍生物在不饱和醛选择性加氢应用中的最新进展和技术挑战,并对这些材料的性能进行了讨论,试图通过催化剂结构、催化剂性能、反应机理等分析,为进一步合理设计有效的催化剂,实现更高的不饱和醇收率提供研究思路。     

金属-有机框架材料在光电催化水分解领域的研究进展

光催化分解水是将太阳能转化为化学能的有效手段之一. 相比于粉末光催化, 采用H型电解池的光 电催化方法具有材料选择范围大、 载流子迁移和分离效率高、 电极易于回收等优点. 近年来, 金属有机框架 材料(MOFs)在光电催化水分解领域得到越来越多的应用. 相比于传统无机催化剂, MOFs光电极具有比表面积大、 结构易于调控等独特优势. 本文按照MOFs的应用形式分为纯MOFs、 MOFs与其它催化剂的复合结构和MOFs衍生物3类, 总结了近年来MOFs在光电催化水分解领域的研究现状和进展, 介绍了光催化/电催化领域的部分典型研究成果, 最后讨论了MOFs在光电催化水分解领域研究的重点和热点, 并对其未来发展做出了展望.     

离子液体功能化金属有机骨架材料催化CO2环加成反应研究进展

金属有机骨架(Metal-organic frameworks, MOFs)材料因具有超大比表面积、可修饰的化学结构、可调的孔隙形状和大小、开放的金属位点等独特的结构优越性而被广泛用于催化CO₂环加成反应的研究中。然而,大部分MOFs材料在此反应中往往需要在助催化剂或溶剂的存在下才能发挥其催化性能,这也导致了产物分离困难、资源浪费等问题。因此,开发能够单独催化CO₂环加成反应的MOFs材料成为当前科学家们研究的热点。在MOFs骨架上或孔腔内修饰离子液体是构筑此类催化体系的一种重要途径。本文对近年来这类MOFs的构筑策略、催化CO₂环加成反应的性能以及催化机理进行了总结,同时还对MOFs组成、形貌以及催化反应条件等因素对催化活性的影响进行了探讨。     

中空MOFs材料制备及电催化应用的研究进展

水分裂、金属-空气电池和燃料电池等能源转换技术对解决未来的能源危机和环境问题至关重要.氧还原反应(ORR)、氧析出反应(OER)和氢析出反应(HER)作为其核心反应,存在反应动力学速率较慢的问题,因此,开发研制高效的非贵金属电催化剂具有重要意义.金属有机骨架(MOFs)材料因具有高度可调的组成和多孔晶体结构,在不同的应用领域引起了越来越多的关注.中空MOFs纳米材料具有MOFs材料高度可调的组成和结构优势,又具有中空结构纳米材料的优点(如更快的物质传输、更丰富的孔隙率、灵活多变的活性组分、更多的暴露活性位点及对苛刻条件的更好相容性等),在电催化领域显现出巨大的应用潜力.本文对近几年来基于中空结构MOFs材料的制备及在电催化方面应用的研究进展进行了综合评述,并对该领域面临的挑战和发展前景进行了总结和展望.     

离子液体功能化金属/共价-有机框架材料在催化反应中应用

离子液体（ILs）功能化的金属有机框架（MOFs）和共价有机框架（COFs）材料兼具离子液体和MOFs/COFs的优点，是一种极具潜力的复合催化材料。MOFs和COFs材料固定的孔结构及较大的比表面积为负载高分散催化中心提供了天然的物理空间；多孔结构促使催化剂与反应物充分接触；丰富的孔道有利于运输催化反应底物和产物，进而实现催化反应的高效进行。特别是离子液体片段的引入，可以作为催化活性中心的配体（稳定剂）或分散剂，同时能够有效改善MOFs和COFs材料孔道和活性中心周围的微环境。此外，还可以充分利用离子液体片段在适当的反应条件下转化为氮杂环卡宾配体的特点，在MOFs和COFs材料中引入氮杂环卡宾有机金属配合物。因此，我们对近几年来离子液体功能化的MOFs或COFs催化体系在CO2环加成、CO2还原、C-C偶联、羰基化以及其它有机转化反应中的研究应用进行简要综述。并对复合材料在催化领域的发展进行总结和展望。     

双发光MOFs的比率型传感和可视化检测应用*

通过[Cu(NH₃)₄]²⁺和EDTA-Ca配合物,引出金属有机骨架(MOFs),揭示刚性多齿配体使MOFs形成无限延展多孔结构的本质。从单一荧光引出双荧光,到比率型荧光传感和可视化检测应用。MOFs丰富的金属离子和配体组成以及多孔结构,为实现双荧光奠定了基础。镧系金属的电子结构使其可以发出可见光。基于此,通过几个多发光MOFs,特别是镧系金属MOFs的比率型荧光和可视化传感应用,将教学知识点与科学前沿结合到一起,一方面加深学生对知识点的理解和掌握,另一方面激发学生运用知识,探索未知的兴趣。     

MOFs传感器在癌症及其生物标志物检测中的应用

癌症是世界上最致命的疾病之一,因此癌细胞的有效捕获和敏感检测对基础研究以及临床诊断和治疗都具有重要意义。基于金属有机骨架(MOFs)的催化活性和固有的发光性能等特点,MOFs已被成功地开发为传感平台实现对癌症及其标志物的检测。综述了基于MOFs的电化学、荧光、电化学发光、比色传感器在癌细胞及核酸、蛋白质等生物标志物检测中近3年的研究进展,从MOFs材料,检测物类型,检测方法、检测能力等方面进行了综述,并对各自的特点进行了讨论,对以后MOFs纳米材料在癌症检测中的应用进行了展望。     

Photocatalytic degradation of organic pollutants by MOFs based materials: A review

Metal-organic frameworks (MOFs) are currently popular porous materials with research and application value in various fields. Aiming at the application of MOFs in photocatalysis, this paper mainly reviews the main synthesis methods of MOFs and the latest research progress of MOFs-based photocatalysts to degrade organic pollutants in water, such as organic dyes, pharmaceuticals and personal care products, and other organic pollutants. The main characteristics of different synthesis methods of MOFs, the main design strategies of MOFs-based photocatalysts, and the excellent performance of photocatalytic degradation of organic pollutants are summarized. At the end of this paper, the practical application of MOFs, the current limitations of MOFs, the synthesis methods of MOFs, and the future development trend of MOFs photocatalysts are explained.     

Dual-band simultaneous lasing in MOFs single crystals with Fabry-Perot microcavities

Multi-band microlasers based on single microcrystalline materials with Fabry-Perot(F-P) cavities are critically and technologically essential. Here, we demonstrate simultaneous dual-band lasing output(615 and 685 nm) in metal-organic frameworks(MOFs) and organic dyes hybrid single crystals, which support F-P resonances. Through a two-step assembly strategy, two different types of cationic pyridinium hemicyanine dye molecules can be encapsulated into the channel pores of anionic bioMOF-1-2 Me successfully. In addition, the employment of the host-guest system significantly increases the dye loading, enhances luminescent efficiency, and diminishes the aggregation-caused quenching(ACQ) effect in the resultant MOFs/dye composites.This finding not only combines the characteristic of MOFs materials with excellent luminescent properties of organic dyes, but also points out a simple and promising strategy to design multi-band microlasers based on F-P mechanism, opening a low-cost avenue for the rational design of miniaturized lasers in the future.     

Finding MOFs for highly selective CO2/N2 adsorption using materials screening based on efficient assignment of atomic point charges

Electrostatic interactions are a critical factor in the adsorption of quadrupolar species such as CO(2) and N(2) in metal-organic frameworks (MOFs) and other nanoporous materials. We show how a version of the semiempirical charge equilibration method suitable for periodic materials can be used to efficiently assign charges and allow molecular simulations for a large number of MOFs. This approach is illustrated by simulating CO(2) and N(2) adsorption in ~500 MOFs; this is the largest set of structures for which this information has been reported to date. For materials predicted by our calculations to have promising adsorption selectivities, we performed more detailed calculations in which accurate quantum chemistry methods were used to assign atomic point charges, and molecular simulations were used to assess molecular diffusivities and binary adsorption isotherms. Our results identify two MOFs, experimentally known to be stable upon solvent removal, that are predicted to show no diffusion limitations for adsorbed molecules and extremely high CO(2)/N(2) adsorption selectivities for CO(2) adsorption from dry air and from gas mixtures typical of dry flue gas.     

以MOFs为前驱体的多孔金属氧化物催化剂研究进展

多孔金属氧化物具有高比表面积、大孔径、特殊的形貌和结构特性,广泛应用于催化、锂离子电池、太阳能电池、气敏传感器等领域。金属有机骨架材料(MOFs)是一类具有周期性网络结构的新型多孔晶体材料,在气体存储、气体分离、催化等领域具有重要的应用价值。近年来,以MOFs为前驱体制备多孔碳和多孔金属氧化物成为MOFs应用领域一个新的研究热点。本文主要综述了以MOFs为前驱体制备的多孔金属氧化物和多孔金属氧化物/碳复合物在CO氧化、催化产氢、异丁烷脱氢、环已烯氧化、醇直接氧化为酯、醛氧化酰胺化反应、光催化降解有机物和氧还原反应等方面的应用。     

Recent Advances of MOFs and MOF-Derived Materials in Thermally Driven Organic Transformations

Owing to the almost boundless structural tunability, MOF and MOF-derived catalysts have recently exhibited structures of higher complexity, and hence, have demonstrated activity in a wide array of organic transformations. These reactions have a broad range of important applications ranging from pharmaceuticals to agriculture. Given the increasing number of publications in the area, this Minireview is focused on the most recent advancements in thermally driven organic transformations using both MOFs, nanoparticle@MOF (NP@MOF) composites, and several classes of MOF-derived materials. The most recent advancements made in materials design and the utility of these materials in a broad range of reactions are discussed.     

Natural lotus root-based scaffolds for bone regeneration

A high incidence of bone defects and the limitation of autologous bone grafting require 3 D scaffolds for bone repair. Compared with synthetic materials, natural edible materials possess outstanding advantages in terms of biocompatibility, bioactivities and low manufacturing cost for bone tissue engineering. In this work, attracted by the natural porous/fabric structure, good biocompatibility and bioactivities of the lotus root, the lotus root-based scaffolds were fabricated and investigated the...     

MOFs – Metallorganische Gerüststrukturen. Funktionale poröse Materialien

MOFs (metal‐organic frameworks) have developed into an important class of materials. This is due to their potential application in the fields of catalysis, gas storage, nanoreactors, or drug release. MOFs are comprised of isolated metal ions or metal‐oxygen clusters, chains or layers, which are connected via organic linkers to form three‐dimensional frameworks of outstanding porosity. Owing to their modular assembly, the pores of MOFs can be tailored using functionalized linkers, following the principle of reticular chemistry.     

极性基团修饰金属有机框架材料吸附分离CO2的研究进展

基于从废气中脱除回收CO_2的迫切现实需求,通过对金属有机框架材料(MOFs)进行功能化修饰,构筑具有高容量、高选择性CO_2吸附的耐水MOFs材料成为当前的研究热点。本文首先对MOFs材料的高压CO_2吸附进行了简单的介绍;进而,针对实际工业应用中低压条件下的CO_2捕集,对作为调节MOFs材料CO_2低压吸附分离性能的有效手段的含氮以及杂原子极性基团修饰进行了综述。     

Metal‐Organic Frameworks (MOFs) as Functional Supramolecular Architectures for Anion Recognition and Sensing

Metal‐organic frameworks (MOFs) have experienced a tremendous growth during last few decades as porous crystalline molecular materials. The comprehensive effect of structural diversity, tunability and high surface area makes MOFs suitable for multifarious applications. MOFs can act as potential receptors toward different target components along with ionic species, small molecules, solvents, explosives etc. Anion recognition remains an important phenomena due to its involvement in many chemical and biological processes. Ligand designing, incorporation of appropriate functional groups and post‐synthetic modifications are key strategies in MOFs for selective recognition and scavenging of environmentally toxic and detrimental anions (i. e. cyanide, oxo‐anions etc.). The main focus of this personal account is on our research towards development and potential applications of MOFs with special emphasis on selective and sensitive anion sensing.