金属有机框架(MOFs)基光催化剂的设计及其在太阳能燃料生产和污染物降解领域的研究进展

金属有机骨架(MOFs)具有较高的比表面积,丰富的金属/有机物种,较大的孔体积以及结构和成分可调节的特性,因此在太阳能燃料生产和污染物的光降解领域具有广泛的应用.根据其结构特点,研究者们主要从有机配体和孔道结构两方面对MOFs进行调控:(1)对有机配体进行修饰,如将杂原子、羟基、卤素原子、金属离子、生物大分子等引入MOFs结构;(2)将无机纳米粒子引入MOFs孔道内,如将贵金属、金属氧化物、多金属氧酸盐等纳米粒子封装在MOFs的孔道内.这些策略可有效增强MOFs的导电性、稳定性等,并进一步提高MOFs基催化剂的光催化性能.本文首先概述了四种经典MOFs类型,即UiO,ZIF,MIL和PCN系列的结构特点和催化性能.其次,总结了在设计MOFs基光催化材料过程中,根据不同类型MOFs特点着重考虑的五方面因素,即稳定性、能带结构、吸附作用、选择性和电导性.再次,讨论了提高MOFs基光催化剂活性的策略,如助催化剂修饰、构建异质结、配体或金属中心修饰和缺陷工程.最后,总结了MOFs基光催化材料在催化还原CO₂、分解水制氢和降解有机污染物反应中的应用进展及影响其催化性能的主要因素.尽管MOFs基光催化材料研究已经取得了令人瞩目的进展,但对MOFs基光催化剂进行可控设计制备仍然存在挑战.如何实现纳米MOFs基光催化材料的制备与规模化生产、可调缺陷MOFs基光催化材料的精准设计、开发高稳定性的MOFs基光催化材料等仍需进一步探索.因此,未来需要从MOFs的纳米化合成、复合材料界面结构的精准调控、催化活性机制与稳定性关系等方面对MOFs基光催化材料进行深入的研究.     

金属-有机骨架材料的改性方法及其光催化制氢应用

能源问题一直是关乎人类命运的重要问题,光催化制氢被认为是有望解决这一问题的潜在途径之一.金属有机框架(MOFs)由于其多孔、高比表面积、带隙可调等特性,在光催化制氢方面得到了广泛关注.我们综述了近些年来在金属-有机骨架材料光催化制氢领域的各种改性方法 ,包括修饰有机连接配体、修饰金属中心、金属纳米粒子沉积、染料敏化与其他功能材料结合等.概括了改性后的MOFs光催化制氢性能,指出了MOFs基光催化制氢存在的问题和可能的解决思路,并展望了MOFs基光催化制氢剂的绿色未来.     

用于电解水制氢的过渡金属有机骨架基催化剂

金属有机骨架(MOFs)材料因具有无机和有机的杂合性质、高度有序的多孔性、结构可修饰性、比表面积大和孔隙率高等特点,在催化领域具有广阔的应用前景。本文从氢能的开发利用角度出发,在纯MOFs、MOFs复合及衍生材料三个方面对近十年来过渡金属MOFs基催化剂在电解水制氢方面的重要研究进展进行了综述,着重针对材料的合成进行了探讨,以及在基础研究和产业应用的角度指出当前过渡金属MOFs基制氢催化剂面临的挑战和机遇,对其应用前景进行展望。     

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.     

Recent Advances of Metal-Organic Frameworks-based Nanozymes for Bio-applications

Artificial nanoenzymes with enzyme-like catalytic activity have gradually become an alternative to natural enzymes due to their low production cost, high stability, and good tolerance. In recent years, various enzyme mimics have emerged with the rapid development of nano-teclnology. Metal-organic frameworks(MOFs) are a novel class of porous inorganic-organic hybrid materials made from metal ions/clusters and organic ligands, and MOFs-based nanozymes show great prospect in biosensing, biocatalysis, biomedical imaging, and therapeutic applications, due to unique properties, such as high specific surface area, high porosity, tunable morphology, and excellent biocatalytic properties. In this paper, the recent progresses concerning MOFs-based nanozymes are systematically summarized, including the synthesis, design strategies and related applications, which are divided into two major categories, namely, MOFs structured nanoenzymes and MOFs composite structured nanoenzymes. Meanwhile, the applications of various classifications of MOFs research are introduced. At the end, current challenges and future perspectives of MOFs-based nanozymes are also discussed. It is highly expected that this review on this important area can provide a meaningful guidance for tumor therapy, biosensing and other aspects.     

MOFs基材料在光催化CO2还原中的应用

系统总结了金属有机框架(MOFs)基材料在光催化还原CO₂中的最新研究进展, 其中包括MOFs直接作为光催化剂和作为复合光催化2个主要部分, 讨论了MOFs基光催化剂在催化还原CO₂方面展现出的独特优势, 并对MOFs基光催化剂的结构稳定性与CO₂转化效率等问题进行讨论与分析, 对未来发展趋势进行了展望.     

2D MOFs-based Materials for the Application of Water Pollutants Removing: Fundamentals and Prospects

Water quality can have serious impacts on human health. One crucial issue of water pollution seriously affects our safety due to the continually emerging of discovered anthropogenic pollutants. The water treatment technologies are persistent improvement to adapt such new contaminants, which accelerates the evolution of materials science to explore solving the problems. Metal-organic Frameworks (MOFs) as the significant porous and multi-dimensional networks has been concerned for toxic pollutant elimination, especially probed the applications of outstanding layered 2D skeletons MOFs-based materials. The emphases of this review highlight the 2D MOFs-based materials used in water remediation and treatment strategies including adsorption and catalysis methods. Further, the prospects and challenges of 2D MOFs-based materials for water treatments applications would be surveyed meticulously for the future research and development.     

二氧化钛基Z型光催化剂综述(英文)

TiO_2具有无毒、耐腐蚀、高稳定和低成本等特点,已被广泛应用于光催化领域.然而,TiO_2的禁带较宽,只能吸收仅占太阳光4%的紫外光部分,从而严重限制了TiO_2光催化材料对太阳光的有效应用.目前很多方法被用来提高TiO_2光催化效率,如金属/非金属掺杂、贵金属负载、异质结构建和与碳材料复合等,这些策略在提高光催化剂的光催化效率中,涉及到如何兼顾太阳光利用和光生空穴和电子氧化还原能力两者之间的平衡.通常,半导体禁带宽度越窄,半导体的光谱响应范围越宽、太阳光利用越多,但光生空穴和电子氧化还原能力越弱.因此,想要提高TiO_2的光催化性能,应考虑以下两个方面的平衡:即降低带隙宽度,拓展半导体的光谱响应范围;与之同时使价带电位更正,导带电位更负之间的平衡.然而,这两个点是相互矛盾的,因此很难在单组分光催化剂中同时实现这两点.然而,Z型光催化剂可以同时满足这两点要求,即:降低半导体的带隙,同时使导带更负,价带更正,因为Z光催化系统利用了两种半导体的优势,其电荷转移机制类似于自然界中绿色植物的光合作用,其中的载流子传输途径包括两步激发,类似于英文字母"Z",Z型光催化剂因此而得名.Z型光催化剂既能保留较高还原能力的光生电子和又能保留较高氧化能力的光生空穴,由于Z型光催化剂特有的优点,在光催化领域的应用越来越广泛.本文综述了TiO_2基Z型光催化剂的最新研究进展,其中包括:Z型光催化机理、应用范围和光催化活性改进方法.Z型光催化剂分为传统液相Z型光催化体系,全固态Z型光催化体系,以及最近几年发展起来的直接Z型光催化体系.它们的主要应用包括:光催化分解水产氢、二氧化碳还原制备太阳燃料、有机污染物光催化降解.论文进一步讨论了提高TiO_2基Z型光催化剂性能的方法,包括pH值调控、电子导体选择、助催化剂使用、掺杂改性、组织形貌控制、两种半导体质量比优化等.最后,提出了TiO_2基Z型光催化剂今后面临的挑战和发展前景展望.     

基于金属有机骨架材料的生物传感器在食源性致病菌或毒素检测中的应用

食源性致病菌或其产生的毒素污染的食物会给人体健康带来严重威胁,并造成巨大的经济损失。近年来,金属有机骨架材料(MOFs)作为一种新型的多孔晶体材料,因其具有大的表面积、高的孔隙率等特点,受到人们的广泛关注。将MOFs与生物传感器结合用于食源性致病菌或毒素的检测引起了研究者的兴趣。基于此,本文介绍了MOFs用于生物传感器的优势,概述了MOFs在不同的电化学和光学生物传感器的应用,综述了基于MOFs的生物传感器在致病菌或毒素的研究进展,讨论了基于MOFs的生物传感器在致病菌或毒素所面临的挑战和展望。     

金属-有机框架衍生的多功能光催化剂

在光催化过程中,光催化剂被太阳能激发产生光生电子和空穴,来实现环境净化或能量转换,是应对全球变暖和能源短缺的有效途径之一.然而,光催化技术面临的主要瓶颈问题是光生载流子的低分离效率和高反应能垒.而催化剂本身的特性对这一点起到了决定性的作用.因此,催化剂的合理设计和改性是提高光催化效率的关键.金属有机框架(MOFs)是一...     

金属有机骨架材料MIL-101及其改性材料去除环境污染物的研究进展

目前我国水环境以及空气面临着严峻的污染形势,许多危害人身体健康的污染物亟待治理。 金属有机骨架作为目前新兴的多孔材料,具有高孔隙率、高比表面积、结构可调性以及不饱和金属位点等特点。 这使得金属有机骨架材料具有一定的环境污染物去除能力。 围绕对苯二甲酸铬金属有机骨架材料(MIL-101)及其功能化修饰的改性材料的结构信息展开,总结了材料的主要合成方法,对功能化修饰的方法和原理进行分析,重点分析了这种材料在环境污染物去除等方面的应用研究进展,包括它在重金属离子、农药、抗生素、有机染料、碘离子等污染物的吸附处理领域的应用, 以及在污染物的监测和环境风险预警方面的应用潜力。 指出了材料在制备成本、反复利用次数、污染物后续处理等方面仍然存在的问题。     

Recent advances in the application of metal organic frameworks using in advanced oxidation progresses for pollutants degradation

Metal-organic frameworks (MOFs) materials with highly ordered and porous crystalline structure, have excellent performance in advanced oxidation progresses (AOPs) for organic contaminants degradation in water treatment. This review intends to summarize the timely references and insights for the recent advances in MOFs that are used in AOPs. Starting with the preparation methodologies, including conventional hydrothermal method, electrochemical method, sol-gel method, and emerging microwave and ultrasound assisted synthesis methods. Application and mechanism for MOFs using in various AOPs of Fenton-like, photocatalysis, catalytic ozonation, persulfate catalysis and other emerging oxidation methods are emphatically discussed. We hope this review can comprehensively summarize the research and application progress of MOFs in AOPs, deepen the understanding of the catalytic mechanisms.     

金属有机骨架材料在吸附分离大气污染物中的应用

大气污染问题是关系人民生命健康和经济社会和谐发展的重大问题.因此需要开发高效的吸附材料用于大气污染物的吸附和分离.金属有机骨架材料(MOFs)是一类新型的多孔材料,该材料具有结构多样、孔结构有序、大比表面积和高孔隙率等结构特点.MOFs通过调节有机配体的长度和官能团调节孔径和孔道尺寸,并进行功能化修饰在孔道中引入功能性...     

金属有机骨架及其复合材料在固相微萃取中的制备及应用

金属有机骨架材料是近几年涌现出的一类新型多功能多孔固体材料,由金属离子和有机配体自组装形成.基于其比表面积高、孔隙率大、热稳定性好和结构与功能多样化等优点,此类材料可作为潜在的吸附剂来对水体等环境污染物进行预处理分析.此外,金属有机骨架材料和不同功能材料如碳基材料、分子印迹聚合物材料以及磁性纳米粒子等组装形成的金属有机骨架复合材料,其整体性能较优于母体金属有机骨架材料.因此,金属有机骨架复合材料在样品预处理方面的应用也引起了研究者的极大兴趣和广泛关注.结合自己的研究工作,对近5年的金属有机骨架材料以及金属有机骨架复合材料,主要在固相微萃取样品预处理方面的应用进行了综述,并对其发展前景进行了展望.     

Two-dimensional MOF Cu-BDC nanosheets/ILs@silica core-shell composites as mixed-mode stationary phase for high performance liquid chromatography

Here, silica microspheres were decorated with two-dimensional metal–organic frameworks (2D MOFs) nanosheets and ionic liquids, and evaluated as the mixed-mode stationary phase for chromatographic separation. The ionic liquids were used to assist the synthesis of 2D MOFs nanosheets, and also acted as adhesives among the nanosheets and silica. In contrast with the 2D MOFs-based column without ionic liquids and commercial columns, the prepared column exhibited enhanced chromatographic separation performance for partially hydrophilic compounds such as alkaloids, sulfonamides and antibiotics, etc. In addition to excellent chromatographic repeatability and stability, it has also been verified that the composites could be easily and repeatedly prepared. The relative standard deviation of the retention time of the same type of analyte between the three batches of materials was ranging from 0.21% to 1.7%. In short, these results indicated that the synthesized composites were promising separation material for liquid chromatography, which made it possible to broaden the application of 2D MOFs in the field of chromatography.     

A General Preparation of Solid Solution-Oxide Heterojunction Photocatalysts through Metal–Organic Framework Transformation Induced Pre-nucleation

Solid solution-oxide heterostructures combine the advantages of solid solution and heterojunction materials to improve electronic structure and optical properties by metal doping, and enhance charge separation and transfer in semiconductor photocatalysts by creating a built-in electric field. Nevertheless, the effective design and synthesis of these materials remains a significant challenge. Here, we develop a generally applicable strategy that leverages the transformable properties of metal–organic frameworks (MOFs) to prepare solid solution-oxide heterojunctions with controllable structural and chemical compositions. The process consists of three main steps. First, MOFs with different topological structures and metal centers are transformed, accompanied by pre-nucleation of a metal oxide. Second, solid solution is prepared through calcination of the transformed MOFs. Finally, a heterojunction is formed by combining solid solution with another metal oxide group through endogenous overflow. DFT calculations and study on carrier dynamics show that the structure of the material effectively prevents electrons from returning to the bulk phase, exhibiting superior photocatalytic reduction performance of CO₂. This study is expected to promote the controllable synthesis and research of MOF-derived heterojunctions.     

Enhanced Charge Transfer Process and Photocatalytic Activity over a Phosphonate-based MOF via Amorphization Strategy

Recently, amorphous materials have gained great attention as an emerging kind of functional material, and their characteristics such as isotropy, absence of grain boundaries, and abundant defects are very likely to outrun the disadvantages of crystalline counterparts, such as low conductivity, and ultimately lead to improved charge transfer efficiency. Herein, we investigated the effect of amorphization on the charge transfer process and photocatalytic performance with a phosphonate-based metal–organic framework (FePPA) as the research object. Comprehensive experimental results suggest that compared to crystalline FePPA, amorphous FePPA has more distorted metal nodes, which affects the electron distribution and consequently improves the photogenerated charge separation efficiency. Meanwhile, the distorted metal nodes in amorphous FePPA also greatly promote the adsorption and activation of O₂. Hence, amorphous FePPA exhibits a better performance of photocatalytic C(sp³)−H bond activation for selective oxidation of toluene to benzaldehyde. This work illustrates the advantages of amorphous MOFs in the charge transfer process, which is conducive to the further development of high performance MOFs-based photocatalysts.     

功能化金属有机骨架材料去除饮用水污染物的研究进展

金属有机骨架(MOFs)材料是一类以过渡金属为中心、含杂原子的有机物为配体、通过配位作用形成的周期性网络多孔晶体材料。与其他的多孔材料相比,MOFs配体种类繁多,比表面积极大,孔径大小可调控且具有特殊(饱和或不饱和)的金属位点,在气体存储、催化、吸附与分离等领域有广阔的应用前景。近年来,功能化MOFs对污染物的富集和去除成为学者关注的热点。这是由于通过对MOFs进行功能化修饰,能够改变MOFs的孔径大小、表面带电性质等物化性质,从而实现对目标物更高效的吸附。该文综述了近年来功能化MOFs对饮用水污染物吸附的研究进展,包括饮用水污染物的类型及危害、功能化MOFs的制备方法以及去除饮用水污染物的应用,并对今后的发展前景进行了展望。     

Suspending Ion Electrocatalysts in Charged Metal–Organic Frameworks to Improve the Conductivity and Selectivity in Electroorganic Synthesis

Electroorganic synthesis is an environmentally friendly alternative to traditional synthetic methods; however, the application of this strategy is heavily hindered by low product selectivity. Metal–organic frameworks (MOFs) exhibit high selectivity in numerous catalytic reactions; however, poor conductivity heavily limits the application of MOFs in electroorganic synthesis. To realize the electrocatalytic application of MOFs in selective electroorganic synthesis, a practically applicable strategy by suspending ion electrocatalysts in charged MOFs is herein reported. This approach could markedly improve the product selectivity in electroorganic synthesis. In the electrocatalytic oxidative self‐coupling of benzylamine experiments, the imine product selectivity is markedly improved from 61.3 to 94.9 %, when the MOF‐based electrocatalyst is used instead of the corresponding homogeneous electrocatalyst under the identical conditions. Therefore, this work opens a new route to improve the product selectivity in electroorganic synthesis.     

One-dimensional HKUST-1 nanobelts from Cu nanowires

The controllable synthesis of one-dimensional(1D) structural morphology of metal-organic frameworks(MOFs) is significant for its application in catalysis,sense and gas separation.In this communication,we report a simple and moderate synthetic strategy to obtain uniform HKUST-1 nanobelts(NBs) by using copper nanowires(Cu NWs) as a metal source as well as a template.The control experiments showed that synergy between metal dissolution rate and crystal formation plays a key role in the formation of nanobelts.Our study represents an attractive synthetic strategy of 1 D MOFs-based material for applications.