Pairing without γ-Pocket in the La3Ni2O7 Thin Film

Abstract

The recent discovery of high-temperature superconductivity (HTSC) in the La3Ni2O7 ultrathin film at ambient pressure has aroused great research interest. The γ-pocket formed by the bonding dz2 band, which was previously proposed to be crucial in the pairing mechanism of pressurized bulk La3Ni2O7, is reported to be either present or absent here by different experimental groups, giving rise to the problem: what is the pairing mechanism and pairing nature without the γ-pocket? Here, we start from a band structure obtained via density-functional-theoretical calculation, which exhibits no γ-pocket. Then, equipped with electron interactions, we study the pairing nature via combined weak- and strong- coupling approaches, which provide consistent results. In the weak-coupling study, the nesting between the α- and β- pockets leads to an s-wave pairing in which the gap signs on the two pockets are opposite, as provided by our random-phase-approximation based calculations. In real-space, the pairing pattern is dominated by the interlayer pairing of the dx2-y2 orbital. In the strong-coupling study, as the dz2 orbitals are nearly half-filled and hence localized, the dx2-y2 orbitals carry the HTSC. Driven by the interlayer superexchange transferred from the dz2 orbital through the Hund's rule coupling, the dx2-y2 orbital electrons form interlayer s-wave pairing, as suggested by our slave-boson-mean-field study on the related two-orbital t-J model. Projected onto the Fermi surface, this pairing just gives the s-wave pattern consistent with that obtained in the weak-coupling study. Our result is consistent with that obtained in recent scanning tunneling microscopy experiment.