Perovskite-related ReO3-type structures

Evans, Hayden A.; Wu, Yirong; Seshadri, Ram; Cheetham, Anthony K.

doi:10.1038/s41578-019-0160-x

Cited by 77 publications

(67 citation statements)

References 255 publications

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“…Precise size and shape matching between the guest and host cavity is critical for preserving the inherent lattice parameters of the perovskites without structure perturbation of either the host frameworks or the guest crystals. The ReO 3 ‐type structure is an interesting variation of perovskite with a vacant A‐site . MOFs with the ReO 3 ‐type structure are of particular interest: when long ligands such as carboxylates and azolates are used at the X‐sites, the inner space can be large enough to host guest components.…”

Section: Key Opportunities Enabled By the Compositesmentioning

confidence: 99%

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

et al. 2020

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This Review examines how the intermarriage of perovskite and metal‐organic framework crystals brings new paradigms for material design and functionality. The strategic combination of halide perovskites and metal–organic frameworks (MOFs) has generated a new family of porous composite materials that will enable new applications, including optoelectronic, catalysis, sensing, and data encryption. This Review surveys the current progress of this exciting new area. Fundamental aspects, including perovskite nucleation and growth, heterojunction electron–hole transfer, electronic structure, and luminescence within confined spaces, are highlighted, with suggestions of approaches by which guest confinement within MOFs can be synthetically designed. We further address the underlying principles and discuss the new insights and tools for the manipulation of these composite materials for the development of synthetic microporous semiconducting composites, as well as new strategies for host–guest interfacial engineering.

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Section: Key Opportunities Enabled By the Compositesmentioning

confidence: 99%

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

et al. 2020

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“…This geometry can be viewed as a perovskite-type ABX 3 structure with vacant A-sites and tilting of the BX 6 octahedra. The VF 3 polytype can be derived from the non-tilted ReO 3 structure (Pm 3m, Z ¼ 1) 22 by enforcing tilting of the octahedra (a À a À a À type tilting in Glazer's notation). 23 It's noteworthy to point out that phase I of TeO 3 is the only example of a trioxide adopting the VF 3 -type structure.…”

Section: Introductionmentioning

confidence: 99%

High-pressure phase transition of AB₃-type compounds: case of tellurium trioxide

2021

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“…For example, the most obvious structural candidate would be the ReO 3 -type structure, 22,23 which has a perovskite architecture with no cation in the cavity (i.e., MX 3 ).…”

Section: Introductionmentioning

confidence: 99%

Understanding the Structural and Electronic Properties of Bismuth Trihalides and Related Compounds

Deng

Wei

et al. 2020

Inorg. Chem.

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Bismuth trihalides, BiX 3 (X F, Cl, Br and I) have been thrust into prominence recently due to their close chemical relationship to the halide perovskites of lead, which exhibit remarkable performance as active layers in photovoltaic cells and other optoelectronic devices. In the present work we have used calculations based on density functional theory to explore the energetics and electronic properties of BiX 3 in a variety of known and hypothetical structure types. The results for BiX 3 are compared with those obtained for the halides of the later rare-earths, represented by YX 3 and LuX 3 . The relative thermodynamic stabilities of the known and hypothetical structures are calculated, along with their band gaps. For the BiX 3 systems we have explored the role of 1 lone pair effects associated with Bi(III), and for BiI 3 we have compared the predicted structural behaviour as a function of pressure with the available experimental data. We have also attempted to synthesize LuF 3 in the perovskite-related ReO 3 -type structure, which is predicted to be only ∼ 7.7 kJ mol −1 above the convex hull. This attempt was unsuccessful, but lead to the discovery of a new hydrated phase, (H 3 O)Lu 3 F 10 H 2 O, which is isomorphous with the known ytterbium analogue.

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Perovskite-related ReO3-type structures

Cited by 77 publications

References 255 publications

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

High-pressure phase transition of AB₃-type compounds: case of tellurium trioxide

Understanding the Structural and Electronic Properties of Bismuth Trihalides and Related Compounds

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Perovskite-related ReO3-type structures

Cited by 77 publications

References 255 publications

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

Intermarriage of Halide Perovskites and Metal‐Organic Framework Crystals

High-pressure phase transition of AB3-type compounds: case of tellurium trioxide

Understanding the Structural and Electronic Properties of Bismuth Trihalides and Related Compounds

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Product

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High-pressure phase transition of AB₃-type compounds: case of tellurium trioxide