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Liquid, glass and amorphous solid states of coordination polymers and metal–organic frameworks

Abstract

The field of coordination polymers and metal–organic frameworks has to date focused on the crystalline state. More than 60,000 crystalline metal–organic framework structures, formed from highly ordered arrays of metal nodes connected by organic ligands in at least one dimension, have been identified. However, interest in non-crystalline systems is growing, with amorphous solids, glasses and liquids identified as possessing similar metal–ligand bonding motifs to their crystalline cousins. In this Review, we provide an overview of the structural design, properties and potential applications of non-crystalline coordination polymers and metal–organic frameworks. In particular, we highlight recent reports of glasses that result from the melt quenching of the liquid states of these topical classes of materials. Finally, we provide a perspective on the future of the non-crystalline domain of coordination polymers and metal–organic frameworks.

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Fig. 1: Terminology for crystalline and amorphous states.
Fig. 2: Examples of CPs and MOFs that form liquids and glasses.
Fig. 3: Routes to the fabrication of CP and/or MOF glasses.
Fig. 4: Amorphization of UiO-66.

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Acknowledgements

T.D.B. thanks the Royal Society for a University Research Fellowship (UF150021) and for their continued support.

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Bennett, T.D., Horike, S. Liquid, glass and amorphous solid states of coordination polymers and metal–organic frameworks. Nat Rev Mater 3, 431–440 (2018). https://doi.org/10.1038/s41578-018-0054-3

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