Interlayer Coupling Driven High-Temperature Superconductivity in La3Ni2O7 Under Pressure

Abstract

The newly discovered high-temperature superconductivity in La3Ni2O7 under pressure has attracted a great deal of attentions. The essential ingredient characterizing the electronic properties is the bilayer NiO2 planes coupled by the interlayer bonding of 3dz2 orbitals through the intermediate oxygen-atoms. In the strong coupling limit, the low energy physics is described by an intralayer antiferromagnetic spin-exchange interaction J between 3dx2-y2 orbitals and an interlayer one J between 3dz2 orbitals. Taking into account Hund's rule on each site and integrating out the 3dz2 spin degree of freedom, the system reduces to a single-orbital bilayer t-J model based on the 3dx2-y2 orbital. By employing the slave-boson approach, the self-consistent equations for the bonding and pairing order parameters are solved. Near the physically relevant 14-filling regime (doping δ=0.3 0.5), the interlayer coupling J tunes the conventional single-layer d-wave superconducting state to the s-wave one. A strong J could enhance the inter-layer superconducting order, leading to a dramatically increased Tc. Interestingly, there could exist a finite regime in which an s+id state emerges.