Hole-Doping Effect on Superconductivity in Compressed CeH9 at High Pressure

Abstract

The experimental realization of high-temperature superconductivity in compressed hydrides H3S and LaH10 at high pressures over 150 GPa has aroused great interest in reducing the stabilization pressure of superconducting hydrides. For cerium hydride CeH9 recently synthesized at 80-100 GPa, our first-principles calculations reveal that the strongly hybridized electronic states of Ce 4f and H 1s orbitals produce the topologically nontrivial Dirac nodal lines around the Fermi energy EF, which are protected by crystalline symmetries. By hole doping, EF shifts down toward the topology-driven van Hove singularity to significantly increase the density of states, which in turn raises a superconducting transition temperature Tc from 74 K up to 136 K at 100 GPa. The hole-doping concentration can be controlled by the incorporation of Ce3+ ions with varying their percentages, which can be well electronically miscible with Ce atoms in the CeH9 matrix because both Ce3+ and Ce behave similarly as cations. Therefore, the interplay of symmetry, band topology, and hole doping contributes to enhance Tc in compressed CeH9. This mechanism to enhance Tc can also be applicable to another superconducting rare earth hydride LaH10.

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