Possible $S_\pm$-wave superconductivity in La$_3$Ni$_2$O$_7$

Recently, the bulk nickelate La$_3$Ni$_2$O$_7$ is reported to show signature of high-temperature superconductivity under high pressure above $14$GPa (H. Sun {\it et al.}, arXiv:2305.09586). We analyze the pairing mechanism and pairing symmetry in a bi-layer Hubbard model with two orbitals in the $E_g$ multiplet. In the weak to moderate interaction regime, our functional renormalization group calculations yield $S_\pm$-wave Cooper pairing with dominant $d_{3z^2-r^2}$-orbital content, triggered by spin fluctuations at wave vectors near $(0.84, 0)\pi$ and $(0.75, 0.75)\pi$, up to $C_{4v}$ symmetry. The gap function changes sign across the Fermi pockets. In the strong coupling limit, we develop a low-energy effective theory in terms of atomic one- and two-electron states in the $E_g$ multiplet. The effective theory predicts naturally local pairing (with anti-phase between the two orbitals due to the repulsive inter-orbital pair hopping) and strong singlet pairing on vertical inter-layer bond, where the super-exchange between $d_{3z^2-r^2}$-orbital is the strongest. The real-space structure is consistent with that from functional renormalization group, suggesting the robustness of such a pairing function. We also discuss a possible scenario for the weak insulating behavior under low pressures in terms of the tendency toward the formation of charge order in the strong coupling limit.