Functional materials discovery using energy–structure–function maps

Pulido, Angeles; Chen, Linjiang; Kaczorowski, Tomasz; Holden, Daniel; Little, Marc A.; Chong, Samantha Y.; Slater, Benjamin J.; McMahon, David P.; Bonillo, Baltasar; Stackhouse, Chloe J.; Stephenson, Andrew; Kane, Christopher M.; Clowes, Rob; Hasell, Tom; Cooper, Andrew I.; Day, Graeme M.

doi:10.1038/nature21419

Cited by 401 publications

(518 citation statements)

References 48 publications

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“…The structures were optimized by density functional theory (DFT) calculations, and the energies and densities of the structures were obtained and plotted, which is useful in structural predictions 31 . VT-1 showed the lowest energy and highest density among all the VT members, indicating that VT-1 was the thermodynamically most stable structure (Fig.…”

Section: Resultsmentioning

confidence: 99%

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

et al. 2018

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Design of the structure and composition of crystalline microporous inorganic oxides is of great importance in catalysis. Developing new zeolites is one approach towards this design because of the tunable pore system and high thermal stability. Zeolites are limited to main group elements, which limits their applications in redox catalysis. Another promising choice is zeolitic transition metal oxides providing both porosity and redox activity, thereby further expanding the diversity of porous materials. However, the examples of zeolitic transition metal oxides are rare. Here, we report a new class of zeolitic vanadotungstates with tunable frameworks exhibiting a large porosity and redox activity. The assembly of [W4O16]8− units with VO2+ forms two isomeric porous frameworks. Owing to the complex redox properties and open porosity, the vanadotungstates efficiently catalyse the selective reduction of NO by NH3. This finding provides an opportunity for design and synthesis of inorganic multifunctional materials for future catalytic applications.

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Section: Resultsmentioning

confidence: 99%

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

et al. 2018

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“…Despite the proven value of computational crystal structure prediction (CSP) methods in facilitating the discovery of previously unknown solid forms, molecular solids comprising three or more chemical entities are not routinely studied in such work. This reflects the demands on computing resources and the complexity of the search space, which scales exponentially with the degrees of freedom.…”

Section: Introductionmentioning

confidence: 99%

Efficient Screening for Ternary Molecular Ionic Cocrystals Using a Complementary Mechanosynthesis and Computational Structure Prediction Approach

Shunnar

Dhokale

Karothu³

et al. 2020

Chemistry A European J

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The discovery of molecular ionic cocrystals (ICCs) of active pharmaceutical ingredients (APIs) widens the opportunities for optimizing the physicochemical properties of APIs whilst facilitating the delivery of multiple therapeutic agents. However, ICCs are often observed serendipitously in crystallization screens and the factors dictating their crystallization are poorly understood. We demonstrate here that mechanochemical ball milling is a versatile technique for the reproducible synthesis of ternary molecular ICCs in less than 30 min of grinding with or without solvent. Computational crystal structure prediction (CSP) calculations have been performed on ternary molecular ICCs for the first time and the observed crystal structures of all the ICCs were correctly predicted. Periodic dispersion‐corrected DFT calculations revealed that all the ICCs are thermodynamically stable (mean stabilization energy=−2 kJ mol−1) relative to the crystallization of a physical mixture of the binary salt and acid. The results suggest that a combined mechanosynthesis and CSP approach could be used to target the synthesis of higher‐order molecular ICCs with functional properties.

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“…30 In addition, crystal structure prediction algorithms have afforded significant steps towards rationalising empirical data and show promise for the design of new functional materials. 31,32 This review will cover the application of computational approaches to the research of PMMs. In particular, simulations that produce structural models of these materials in crystalline, amorphous and liquid states will be canvassed and the novel methods of modelling porosity and gas adsorption in these systems will be discussed.…”

Section: Introductionmentioning

confidence: 99%

Application of computational methods to the design and characterisation of porous molecular materials

et al. 2017

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Composed from discete units, porous molecular materials (PMMs) possess unique properties not observed for conventional, extended, solids, such as solution processibility and permanent porosity in the liquid phase. However, identifying the origin of porosity is not a trivial process, especially for amorphous or liquid phases. Furthermore, the assembly of molecular components is typically governed by a subtle balance of weak intermolecular forces that makes structure prediction challenging. Accordingly, in this review we canvass the crucial role of molecular simulations in the characterisation and design of PMMs. We will outline strategies for modelling porosity in crystalline, amorphous and liquid phases and also describe the state-of-the-art methods used for high-throughput screening of large datasets to identify materials that exhibit novel performance characteristics.

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Functional materials discovery using energy–structure–function maps

Cited by 401 publications

References 48 publications

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

Efficient Screening for Ternary Molecular Ionic Cocrystals Using a Complementary Mechanosynthesis and Computational Structure Prediction Approach

Application of computational methods to the design and characterisation of porous molecular materials

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