Jin‐Chong Tan scite author profile

The mechanical properties of hybrid framework materials, including both nanoporous metal-organic frameworks (MOFs) and dense inorganic-organic frameworks, are discussed in this critical review. Although there are relatively few studies of this kind in the literature, major recent advances in this area are beginning to shed light on the fundamental structure-mechanical property relationships. Indeed research into the mechanical behavior of this important new class of solid-state materials is central to the design and optimal performance of a multitude of technological applications envisaged. In this review, we examine the elasticity of hybrid frameworks by considering their Young's modulus, Poisson's ratio, bulk modulus and shear modulus. This is followed by discussions of their hardness, plasticity, yield strength and fracture behavior. Our focus is on both experimental and computational approaches. Experimental work on single crystals and amorphized monoliths involved primarily the application of nanoindentation and atomic force microscopy to determine the elastic moduli and hardness properties. The compressibility and bulk moduli of single crystals and polycrystalline powders were studied by high-pressure X-ray crystallography in the diamond anvil cell, while in one instance spectroscopic ellipsometry has also been used to estimate the elastic moduli of MOF nanoparticles and deposited films. Theoretical studies, on the other hand, encompassed the application of first principles density-functional calculations and finite-temperature molecular dynamics simulations. Finally, by virtue of the diverse mechanical properties achievable in hybrid framework materials, we propose that a new domain be established in the materials selection map to define this emerging class of materials (137 references).

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Chemical structure, network topology, and porosity effects on the mechanical properties of Zeolitic Imidazolate Frameworks

Tan

Bennett

Cheetham

2010

Proc. Natl. Acad. Sci. U.S.A.

492

451

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The mechanical properties of seven zeolitic imidazolate frameworks (ZIFs) based on five unique network topologies have been systematically characterized by single-crystal nanoindentation studies. We demonstrate that the elastic properties of ZIF crystal structures are strongly correlated to the framework density and the underlying porosity. For the systems considered here, the elastic modulus was found to range from 3 to 10 GPa, whereas the hardness property lies between 300 MPa and 1.1 GPa. Notably, these properties are superior to those of other metal-organic frameworks (MOFs), such as MOF-5. In substituted imidazolate frameworks, our results show that their mechanical properties are mainly governed by the rigidity and bulkiness of the substituted organic linkages. The framework topology and the intricate pore morphology can also influence the degree of mechanical anisotropy. Our findings present the previously undescribed structuremechanical property relationships pertaining to hybrid open frameworks that are important for the design and application of new MOF materials.elastic properties | metal-organic frameworks | nanohardness | nanoporosity | zeolitic imidazolate frameworks Z eolitic imidazolate frameworks (ZIFs) represent a unique class of metal-organic frameworks (MOFs) in which the network topology and related properties vary greatly while core chemical connectivity is retained (1, 2). ZIFs currently attract considerable interest by virtue of their exciting potential for hydrogen storage and carbon dioxide capture (3, 4). They adopt porous crystalline structures composed of metal ions and organic linkers, ordered in an analogous fashion to that of silicon and oxygen in zeolites. Specifically, tetrahedral metal centers [typically M ¼ ZnðIIÞ or Co(II)] that are solely coordinated by nitrogen atoms in the 1,3-positions of the imidazolate bridging ligand (Im ¼ C 3 N 2 H − 3 ), subtend an angle of 145°at the M-Im-M center (i.e., analogous to the Si-O-Si angle in silicas and zeolites). Such hybrid architectures can, importantly, give rise to a multitude of extended 3D open frameworks with topologies akin to those found in aluminosilicate zeolites. Over 90 distinct ZIF structures based on 36 of these tetrahedral topologies have been discovered thus far (5). Remarkably, ZIFs combine the classical zeolitic traits of chemical and thermal stability with the rich topological diversity and pore size tunability characteristic of MOFs (6, 7).By and large, research into MOF materials has been motivated by the prospect of discovering new structures with enhanced functional properties for use not only in gas adsorption and separation fields, but also in heterogeneous catalysis and molecular sensing applications (8-11). Indeed, all the aforementioned applications involve subjecting the porous systems to various modes of mechanical stresses and strains, for which their mechanical properties are critical to reach practical implementations. For instance, the open framework needs to exhibit good stiffness, rigidity, and robu...

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A sol–gel monolithic metal–organic framework with enhanced methane uptake

et al. 2017

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A critical bottleneck for the use of natural gas as a transportation fuel has been the development of materials capable of storing it in a sufficiently compact form at ambient temperature. Here we report the synthesis of a porous monolithic metal-organic framework (MOF), which after successful packing and densification reaches 259 cm (STP) cm capacity. This is the highest value reported to date for conformed shape porous solids, and represents a greater than 50% improvement over any previously reported experimental value. Nanoindentation tests on the monolithic MOF showed robust mechanical properties, with hardness at least 130% greater than that previously measured in its conventional MOF counterparts. Our findings represent a substantial step in the application of mechanically robust conformed and densified MOFs for high volumetric energy storage and other industrial applications.

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Zeolitic imidazolate framework (ZIF-8) based polymer nanocomposite membranes for gas separation

Song

Kotrappanavar

Roussenova

et al. 2012

Energy Environ. Sci.

662

420

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As synthesised ZIF-8 nanoparticles (size $ 60 nm and specific surface area $ 1300-1600 m 2 g À1 ) were directly incorporated into a model polymer matrix (MatrimidÒ 5218) by solution mixing. This produces flexible transparent membranes with excellent dispersion of nanoparticles (up to loadings of 30 wt%) with good adhesion within the polymer matrix, as confirmed by scanning electron microscopy, dynamic mechanical thermal analysis and gas sorption studies. Pure gas (H 2 , CO 2 , O 2 , N 2 and CH 4 ) permeation tests showed enhanced permeability of the mixed matrix membrane with negligible losses in selectivity. Positron annihilation lifetime spectroscopy (PALS) indicated that an increase in the free volume of the polymer with ZIF-8 loading together with the free diffusion of gas through the cages of ZIF-8 contributed to an increase in gas permeability of the composite membrane. The gas transport properties of the composite membranes were well predicted by a Maxwell model whilst the processing strategy reported can be extended to fabricate other polymer nanocomposite membranes intended for a wide range of emerging energy applications.

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Hybrid glasses from strong and fragile metal-organic framework liquids

et al. 2015

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Hybrid glasses connect the emerging field of metal-organic frameworks (MOFs) with the glass formation, amorphization and melting processes of these chemically versatile systems. Though inorganic zeolites collapse around the glass transition and melt at higher temperatures, the relationship between amorphization and melting has so far not been investigated. Here we show how heating MOFs of zeolitic topology first results in a low density ‘perfect' glass, similar to those formed in ice, silicon and disaccharides. This order–order transition leads to a super-strong liquid of low fragility that dynamically controls collapse, before a subsequent order–disorder transition, which creates a more fragile high-density liquid. After crystallization to a dense phase, which can be remelted, subsequent quenching results in a bulk glass, virtually identical to the high-density phase. We provide evidence that the wide-ranging melting temperatures of zeolitic MOFs are related to their network topologies and opens up the possibility of ‘melt-casting' MOF glasses.

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Jin‐Chong Tan

Mechanical properties of hybrid inorganic–organic framework materials: establishing fundamental structure–property relationships

Chemical structure, network topology, and porosity effects on the mechanical properties of Zeolitic Imidazolate Frameworks

A sol–gel monolithic metal–organic framework with enhanced methane uptake

Zeolitic imidazolate framework (ZIF-8) based polymer nanocomposite membranes for gas separation

Hybrid glasses from strong and fragile metal-organic framework liquids

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