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W4308657840 abstract "The recent discoveries of metal superhydrides provide a new route to room-temperature superconductors. However, their structure trends and the chemical driving force needed to dissociate H2 and form H covalent network cannot be explained by direct metal-hydrogen bonds. Here, we show that the understanding of superhydrides formation needs a perspective beyond the traditional chemical bonds. By analyzing high-throughput calculation results of metals across the periodic table and in various lattices, we show that, after removing H, the remaining metal lattices exhibit large electron occupations of the nonatomic interstitial orbitals, which matches excellently to H lattices and their wave functions like a template. Furthermore, H lattices consist of 3D aromatic building units that are greatly stabilized by chemical templates of metals near the s−d border. This theory can naturally explain the stability and structure trends of superhydrides and greatly enhance the efficiency of predicting new materials, such as two-metal superhydrides." @default.
W4308657840 created "2022-11-13" @default.
W4308657840 creator A5004258952 @default.
W4308657840 creator A5032481149 @default.
W4308657840 date "2023-02-01" @default.
W4308657840 modified "2023-09-26" @default.
W4308657840 title "Chemical templates that assemble the metal superhydrides" @default.
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W4308657840 doi "https://doi.org/10.1016/j.chempr.2022.10.015" @default.
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