Orbital-Selective d-wave Superconductivity in the Two-Band t-J Model: Possible Applications to La3Ni2O7

Abstract

We investigate superconductivity in a two-band t-J model consisting of an itinerant orbital (orbital-0) and a quasi-localized orbital (orbital-1) using variational Monte Carlo. A robust orbital-selective d-wave superconducting state is found to emerge exclusively from the itinerant orbital. An analysis of the superexchange energy hierarchy shows that the quasi-localized orbital-1 competes with superconductivity by favoring local inter-orbital bound states, which act as energy defects and disrupt phase coherence. Consistently, the superconducting order parameter is monotonically suppressed as the occupancy of orbital-1 increases. Motivated by superconductivity in nickelate La3Ni2O7, these results highlight the essential role of multi-orbital physics beyond the single-band t-J framework and point to a concrete route to enhance Tc: suppressing the involvement of localized dz2-derived orbitals.