Superconductivity in bilayer La3Ni2O7: A review focusing on the strong-coupling Hund's rule assisted pairing mechanism

Abstract

Discovery of high-Tc superconductivity (SC) in the bilayer nickelate series La3Ni2O7 have attracted substantial interest, providing a new platform for exploring unconventional SC. Certain experimental evidence has pointed to a correlated electronic nature, which is the driving force responsible for its high critical temperature (Tc). This work reviews the SC in La3Ni2O7, with a particular focus on theoretical understanding of its pairing mechanism driven by this strong-coupling, Hund-assisted scenario. The electronic landscape is governed by two Eg-orbitals within the bilayer structure of NiO2 planes. The 3dz2 orbital is nearly half-filled and exhibits a stronger localized character, while the 3dx2-y2 is approximately quarter-filled and remains highly itinerant. The localized 3dz2 orbitals experience robust interlayer hybridization, mediated by the 2pz orbitals of the inner apical oxygen atoms. This hybridization generates a strong interlayer antiferromagnetic (AFM) exchange. In the strong coupling regime, Hund's rule coupling aligns the spins of the two Eg orbitals on the same nickel site. The strong interlayer AFM exchange is effectively transferred to the itinerant 3dx2-y2 orbital, generating an effective coupling J within this orbital. This mechanism is captured by a minimal strong-coupling bilayer t-J-J model for the 3dx2-y2 band. Driven by J, 3dx2-y2 electrons can form interlayer Cooper pairs, leading to an extended s-wave pairing SC with high Tc. Meanwhile, the strongly localized 3dz2 electrons tend to form interlayer rung singlets. Due to a lack of phase coherence, these singlets do not directly participate in the SC condensate, but instead give rise to a pseudogap phase.