Theoretical proposal of superconductivity in hole-doped reduced bilayer nickelate La3Ni2O6: a manifestation of orbital-space bilayer model with incipient bands
Abstract
A correspondence exists between the multi-orbital Hubbard model and the bilayer Hubbard model, in which superconductivity is optimized in an incipient-band regime in both cases. In the multi-orbital system, the orbital level offset E plays a role analogous to the interlayer hopping in bilayer systems, and superconductivity is enhanced for large E. We refer to such a multi-orbital model as an orbital-space bilayer model (OSBM). In this study, we theoretically propose that a reduced bilayer nickelate La3Ni2O6 can be a candidate for a superconductor described by OSBM when an appropriate amount of holes is doped. By constructing a tight-binding model based on first-principles calculations, a large E between the Ni dx2-y2 and the other d orbitals is obtained due to the absence of outer apical oxygens. Furthermore, our fluctuation exchange approximation calculations indicate the emergence of s-wave superconductivity driven by interorbital interactions in an incipient-band situation, where the superconducting gap function changes its sign between the dx2-y2 and other d orbital bands. We also investigate the energetic and dynamical stability of the crystal structure under atomic substitution and pressure. Although La3Ni2O7 and La3Ni2O6 share a similar chemical formula, our study shows that an entirely different pairing mechanism can take place in the latter.
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