Pairing Mechanism in Bilayer Nickelate La3Ni2O7 Superconductors

Abstract

The recent discovery of superconductivity with Tc ≈ 80~K in bilayer nickelate La3Ni2O7 provides a new setting in which to test the organizing principles of unconventional high-temperature superconductivity. We show that the gene principle and the collaborative Fermi-surface rule which were previously proposed to unify unconventional high temperature superconductors, extend naturally to this bilayer, multi-orbital system. We identify that there are two antiferromagnetic exchange channels that can provide the dominant pairing force: an interlayer intra-orbital nearest-neighbour exchange J between dz2 orbitals mediated by the inner apical oxygen, and an intralayer inter-orbital nearest-neighbour exchange Jxz between dz2 and dx2-y2 orbitals mediated by the in-plane oxygen. Owing to the bilayer bonding--antibonding splitting and the B1g symmetry of the dx2-y2 orbital, these two channels cooperate to produce a robust s superconducting state with an internal sign reversal between mirror-even and mirror-odd Fermi-surface pockets in momentum space. Both pairing channels maximize the superconducting gap on the β pocket with a form factor (coskx-cosky)2 in momentum space. The result places La3Ni2O7 within a unified framework for unconventional superconductivity while revealing a distinct electronic environment for high-Tc pairing.