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Superconducting Praseodymium Superhydrides

Materials Science 2020-01-15 v2 Superconductivity

Abstract

Superhydrides have complex hydrogenic sublattices and are important prototypes for studying metallic hydrogen and high-temperature superconductors. Encouraged by the results on LaH10, in consideration of the differences between La and Pr, Pr-H system is especially worth studying because of the magnetism and valence-band f-electrons in element Pr. Here we successfully synthesized praseodymium superhydrides (PrH9) in laser-heated diamond anvil cells. Synchrotron X-ray diffraction (XRD) analysis demonstrated the presence of previously predicted F43m-PrH9 and unexpected P63/mmc-PrH9 phases. Moreover, Fm3m-PrH3, P4/nmm-PrH(3-{\delta}) and Fm3m-PrH(1+x) were found below 52 GPa. F43m-PrH9 and P63/mmc-PrH9 were stable above 100 GPa in experiment. Experimental studies of electrical resistance in the PrH9 sample showed the emergence of superconducting transition (Tc) below 9K and a dependent Tc on applied magnetic field. Theoretical calculations indicate that magnetic order and electron-phonon interaction coexist in a very close range of pressures in the PrH9 sample which may contribute to its low superconducting temperature Tc. Our results highlight the intimate connections among hydrogenic sublattices, density of states, magnetism and superconductivity in Pr-based superhydrides.

Keywords

Cite

@article{arxiv.1904.06643,
  title  = {Superconducting Praseodymium Superhydrides},
  author = {Di Zhou and Dmitrii Semenok and Defang Duan and Hui Xie and Xiaoli Huang and Wuhao Chen and Xin Li and Bingbing Liu and Artem R. Oganov and Tian Cui},
  journal= {arXiv preprint arXiv:1904.06643},
  year   = {2020}
}
R2 v1 2026-06-23T08:38:53.248Z