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Exploring the Effect of the Number of Hydrogen Atoms on the Properties of Lanthanide Hydrides by DMFT

Lanthanide hydrogen-rich materials have long been considered as one of the candidates with high-temperature superconducting properties in condensed matter physics, and have attracted great interest. Attempts to investigate the effects of different compositions of lanthanide hydrogen-rich materials are ongoing, with predictions and experimental studies in recent years having shown that substances such as LaH 10 , CeH 9 , and LaH 16 exhibit extremely high superconducting temperatures between 150-250 GPa. In particular, researchers have noted that in those materials an increase in the f character at the Fermi level leads to an increase in the superconducting temperature. Here, we further elaborate on the effect of the ratios of lanthanide to hydrogen in these substances with the aim to bring more clarity to the study of superhydrides in these extreme cases by comparing a variety of lanthanide hydrogen-rich materials with different ratios using the DMFT method, and provide ideas for later structural predictions and material property studies.

preprint2022arXivOpen access
Yao WeiElena ChachkarovaEvgeny PlekhanovNicola BoniniCedric Weber
cond-mat.supr-con
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Yao WeiElena ChachkarovaEvgeny PlekhanovNicola BoniniCedric Weber

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