Superconductivity of bilayer two-orbital Hubbard model for La3Ni2O7 under high pressure

Abstract

By combining density functional theory (DFT) and density matrix renormalization group calculations, we investigate the unusual pressure dependence of superconducting transition temperature (Tc) in the nickelate superconductor La3Ni2O7. Using the hopping integrals and on-site potentials obtained by fitting the DFT band structures, we map a quantum phase diagram of a bilayer two-orbital Hubbard model with increasing pressure in a ladder geometry, which has an intermediate Hubbard repulsion and a Hund's coupling. Near 3/8 filling, we find a strong spin density wave order, which at 3/8 filling shows a real-space spin pattern similar to the spin-charge stripe order along a lattice direction. At 21/64 filling, we find a superconducting phase with interlayer superconductivity (SC) in both the dz2 and dx2-y2 orbitals, as well as in-plane SC in the dz2 orbital. Intriguingly, the SC is weakened with increasing pressure and transits to a Luttinger liquid above 80 GPa, which qualitatively agrees with the experimental observations of decreasing Tc with increasing pressure and a transition to Fermi liquid above 80 GPa in La3Ni2O7. Through a comparative study, we further show that the ratio of interaction to hopping integral, which reduces moderately with increasing pressure, may play a dominant role in the weakening of SC. Our results of this experimentally relevant model not only find a robust SC through suppressing the competing spin density wave order, but also give new insight into the unusual pressure dependence of SC in La3Ni2O7.

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