Electronic structures and superconductivity in Nd-doped La3Ni2O7

Abstract

The recent discovery of high-Tc superconductivity in Ruddlesden-Popper (RP) nickelates has motivated extensive efforts to explore higher Tc superconductors. Here, we systematically investigate Nd-doped La3Ni2O7 using density functional theory (DFT) and renormalized mean-field theory (RMFT). DFT calculations reveal that both the lattice constants and interlayer spacing decrease upon Nd substitution, similar to the effect of physical pressure. However, the in-plane Ni-O-Ni bond angle evolves non-monotonically with doping, increasing to a maximum at 70% ( 2/3) Nd doping level and then falling sharply at 80%, which leads to a reduction in orbital overlap. Moreover, Nd doping has a more pronounced effect on the Ni-dz2 orbital, demonstrating an orbital-dependent effect of rare-earth substitution. Through the bilayer two-orbital t-J model, RMFT analysis further shows an s-wave pairing symmetry, with Tc rising to a maximum at about 70% Nd substitution before declining, in agreement with the transport measurements. The variation in Tc can be traced to the competition between continuously enhanced interlayer superexchange coupling Jz and a gradual decrease in particle density. These results highlight the delicate interplay among structural tuning, orbital hybridization, and superconductivity, providing important clues to design higher-Tc RP nickelate superconductors.

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