Electronic structure, self-doping, and superconducting instability in the alternating single-layer trilayer stacking nickelates La3Ni2O7

Abstract

Motivated by the recently proposed alternating single-layer trilayer stacking structure for the nickelate La3Ni2O7, we comprehensively study this system using ab initio and random-phase approximation techniques. Our analysis unveils similarities between this novel La3Ni2O7 structure and other Ruddlesden-Popper nickelate superconductors, such as a similar charge-transfer gap value and orbital-selective behavior of the eg orbitals. However, different from other Ruddlesden-Popper nickelate superconductors, we do not observe any obvious reconstruction of the Fermi surface from ambient conditions (Cmmm phase) to high pressures (P4/mmm phase). Pressure primarily increases the bandwidths of the Ni eg bands, suggesting an enhancement of the itinerant properties of those eg states. Furthermore, the d3z2-r2 orbital also has a layer-selective behavior because the antibonding-bonding-nonbonding splitting can only be obtained in the trilayer. In addition, we observe a "self-doping" effect from the trilayer to the single-layer sublattices and this effect will be enhanced by overall electron doping. Moreover, we find a leading dx2-y2-wave pairing state that is restricted to the single-layer. Because the effective coupling between the single layers is very weak -- due to the non-superconducting trilayer in between -- this suggests that the superconducting transition temperature Tc in this structure should be much lower than in the bilayer structure.

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