Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Huang, Shengxuan; Wu, Xiang; Hou, Bingxu; Qin, Shan

doi:10.1021/acs.jpcc.0c00054

J. Phys. Chem. C

2020

DOI: 10.1021/acs.jpcc.0c00054

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Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Shengxuan Huang

Xiang Wu

Bingxu Hou

et al.

Abstract: Extensive AO 2 -type transition metal (TM) oxides are experimentally determined or theoretically predicted to adopt the pyrite-type (Pa3̅ ) structure at different pressures, but their physical and chemical properties are largely unknown. Our theoretical calculations demonstrate that the interpolyhedral O−O bond is formed in pyrite-type CoO 2 with low-spin Co 2+ similar to the case of FeO 2 , whereas ferromagnetic CrO 2 and antiferromagnetic MnO 2 belong to dioxides with separate O 2− anions. The oxidation stat… Show more

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Medium-range structure motifs of complex iron oxides

Huang

2022

Journal of Applied Physics

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Natural occurring iron oxides, such as Fe2O3, Fe3O4, and FeO, are abundant on Earth's surface and feature many implications in our daily life since the Iron Age, the final epoch of the prehistory of humanity. The physics of iron oxides is at the frontier of physical research due to their complicated magnetic and electronic properties. What makes it even more intriguing is the introduction of pressure, which not only regulates the crystal structures and physical properties, but also creates new iron-oxide stoichiometry. Recent studies discovered several novel iron-oxygen compounds under various pressure–temperature conditions. Despite different Fe/O ratios, those iron oxides are built upon similar structural units including FeO6 octahedra and trigonal prisms. Complex stoichiometry of pressurized iron oxides is built up by stacking layers of those FeO6 units, and in the medium-range, they are organized by certain structural motifs. In this perspective, we go beyond conventional iron-oxygen binary compounds and reveal the general formation mechanism of complex iron oxide crystals under high-pressure conditions. The results will be helpful for summarizing literary works of iron oxides and exploring novel stoichiometry with optimal physical properties.

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Medium-range structure motifs of complex iron oxides

Huang

2022

Journal of Applied Physics

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Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Cited by 1 publication

References 70 publications

Medium-range structure motifs of complex iron oxides

Medium-range structure motifs of complex iron oxides

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