Fermi surface reconstruction and enhanced spin fluctuations in strained La3Ni2O7 on LaAlO3(001) and SrTiO3(001)
Abstract
We explore the structural and electronic properties of the bilayer nickelate La3Ni2O7 on LaAlO3(001) and SrTiO3(001) by using density functional theory including a Coulomb repulsion term. For La3Ni2O7/LaAlO3(001), we find that compressive strain and electron doping across the interface result in the unconventional occupation of the antibonding Ni 3dz2 states. In sharp contrast, no charge transfer is observed for La3Ni2O7/SrTiO3(001). Surprisingly, tensile strain drives a metallization of the bonding Ni 3dz2 states, rendering a Fermi surface topology akin to superconducting bulk La3Ni2O7 under high pressure, yet with spin fluctuations enhanced considerably beyond pressure effects. Concomitantly, significant octahedral rotations are retained. We discuss the fundamental differences between hydrostatic pressure versus epitaxial strain and establish that strain provides a much stronger control over the Ni eg orbital polarization. The results suggest epitaxial La3Ni2O7, particularly under tensile strain, as interesting system to provide novel insights into the physics of bilayer nickelates and possibly induce superconductivity without external pressure.
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