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1、MetalOrganic Frameworks Team Members:Cao Chang Fu Chu Xian Reporter: Du Meng YuanPublished on Nature Reviews MaterialsCONTENTSIntroduction1Stability of metalorganic frameworks2MOF stability in catalytic systems3Future perspectives4Introduction1Metalorganic frameworks (MOFs) are a scientifically comp
2、elling and functionally evolving class of meso-, micro- and ultramicroporous materials. MOF structures encompass dozens of topologies, including several, such as sodalite and Rho, that are also well known for zeolites. MOFs have been explored for many applications including, but not limited to, gas
3、storage and release, chemical separations, drug delivery, catalysis, light harvesting and energy conversion, and, recently, the degradation of toxic substances such as chemical warfare agentsMOFs are composed of metal nodes and organic linkers that can be systematically tuned in terms of chemical co
4、mposition and precise arrangement an attribute that differs from purely inorganic zeolites,which consist largely of silicon or aluminium ions linked by oxygen atoms.In recent years, the number and diversity of MOF structures have grown significantly, and many water-stable and thermally stable MOFs n
5、ow exist,Enabling an exciting expansion of their application. Depending on the application envisaged, different functional stabilities are important.Stability of metalorganic frameworks2Stability is defined as resistance of the structure to degradation. However, another possible definition is thermo
6、dynamic in origin: many functionally stable MOFs (as well as zeolites) are thermodynamically unstable with respect to alternative typically, denser polymorphs. An active area of MOF research is the development of routes to thermodynamically unstable, but functionally stable, polymorphs.Chemical stab
7、ility12Thermal stability3Hydrothermal stability4Mechanical stabilityStability of metalorganic frameworks1Chemical stabilityThe greatest concerns for the improvement of MOF chemical stability have been largely related to liquid water and water vapour; accordingly, we focus on aqueous solutions. In mo
8、st MOF structures, the chemical weak points are at the nodes more specifically, the metallinker bonds with hydrolysis yielding a protonated linker and a hydroxide(or water) ligated node. Acidic solutions can accelerate the formation of the former, and basic solutions can accelerate the formation of
9、the latter. Although there is no standard method for assessing the stability of MOFs in acidic, basic or neutral solutions, it is often judged by comparing the powder X-ray diffraction (PXRD) pattern of a MOF before and after soaking it in a given aqueous solution. The chemical (acidbase) stability
10、of some representative metalorganic frameworks based on literature data. The bar length indicates the pH range that the metalorganic frameworks (MOFs) can tolerate. An arrow indicates that the MOF can withstand pH14. Selected sections of representative metalorganic framework materials a | ZIF-8b | C
11、u-BTTric | MIL-53(Al)d | MIL-101(Cr)e | PCN-426-Cr(iii) f | (CH3)2NH22 Eu6 (3- OH)8(1,4-NDC)6(H2O)6.Connectivity of Zr6 nodes in zirconium-based metalorganic frameworks and the associated carboxylate molecules required to link nodes together. 2Thermal stabilityThermal degradation of MOFs is,in most
12、cases, a result of nodelinker bond breakage, accompanied or followed by linker combustion. As a consequence, thermal stability is generally related to nodelinker bond strength and the number of linkers connected to each node.Framework catenation more specifically, interpenetration or interweaving of
13、 networks can enhance stability through favourable frameworkframework interactions.Thermogravimetric analysis (TGA) and in situ PXRD are both techniques that can be used to gauge the thermal stability of MOFs.3Hydrothermal stabilityExperimentally, hydrothermal stability is assessed by exposing MOFs
14、to steam at various pressures and temperatures, followed by PXRD analysis and porosity or surface-area measurements.MOF hydrothermal stability can be enhanced by intermolecular or intramolecular forces, such as internal hydrogen bonding or stacking.ZIFs as a class comprise excellent examples of hydr
15、ophobic MOFs, and many ZIFs are hydrothermally stable, making them reasonable candidates for use in humid conditions.4Mechanical stabilityMOFs are known for their extraordinary porosity an attribute that inherently decreases mechanical stability. Therefore, as expected, MOFs are less mechanically st
16、able than zeolites. This instability can manifest itself as phase changes, partial collapse of pores or even amorphization, in response to mechanical loading.Some arrangements of linkers and connectors render MOFs more resistant to deformation and destruction than others. Some computational studies
17、show that mechanical stability tends to be enhanced with shorter linkers. An important practical development that greatly reduces the mechanical performance requirements for MOFs in applications.MOF stability in catalytic systems3The catalytic active site can be several different locations within th
18、e structure. It can be incorporated in the MOF linkers or nodes, or encapsulated,isolated or stabilized by a MOF, or attached to the framework postsynthetically. Regardless of the method used to introduce catalytically active sites, the framework must be stable under catalysis conditions.Solution-ph
19、ase catalysis12High-temperature catalysis of gas-phase reactionsMOF stability in catalytic systems1Solution-phase catalysisThis can constitute acidic, neutral or basic conditions. More specifically, the MOF catalysts need to be able to withstand the conditions appropriate for the chosen reaction. Ca
20、talytic oxidation of water using Ir-containing derivatives of UiO-67. The image shows the structure of UiO-67 and Ir-containing linkers 1 and 2 that are utilized for water oxidation catalysis at pH 1. Catalytic hydrolysis of the nerve agent soman (known as GD) by NU-10002High-temperature catalysis o
21、f gas-phase reactionsThe use of MOFs for gas-phase catalysis is in an early phase, and most investigations have focused on proof-ofconcept reactions such as the oxidation of CO to CO2. We believe that the notion of MOFs as stable and uniform supports for single-site catalysts is an especially exciti
22、ng one, meriting further development.Oxidative dehydrogenation of cyclohexene to benzene using V-UiO-66 as a catalystFuture perspectives4 The extended mechanical and chemical stabilities of MOFs in thin-film form are also attractive goals. The systematic passivation of structural defects withinMOFs
23、that may otherwise be targeted as weak points forattachment, and hence the degradation of the material, is another approach that could offer more stable structuresIn summary, MOFs, as a class of porous materials, have moved from the realm of usually delicate and usually moisture sensitive to nearly routinely designable to withstand harsh physical and chemical conditions. This change will no doubt accelerate the exploration and the application of MOFs, in unique ways, to scientifically and technologically significant problems.