Theoretical study on the electronic properties and multiorbital models of La3Ni2O7 thin films on SrLaAlO4 (001)

Abstract

The realization of ambient-pressure superconductivity in La3Ni2O7 thin films raises a fundamental question: is the metallic ground state driven by lattice strain or interfacial charge reconstruction? Using fully self-consistent DFT+U calculations on La3Ni2O7/SrLaAlO4 heterostructures, we identify that intrinsic hole doping via interfacial Sr interdiffusion is the decisive factor in stabilizing the metallic state. Our 1-unit-cell model accurately reproduces the ARPES-observed Fermi surface, particularly the critical Ni-dz2 derived γ hole pocket, which originates exclusively from the interface-proximal bilayer. Furthermore, comparative tight-binding analysis suggests that the reduced superconducting transition temperature (Tc) in thin films stems from the synergistic suppression of the electronic density of states (DOS) and vertical superexchange coupling (J Z). These findings highlight that interface engineering plays a critical role beyond simple strain imposition in modulating nickelate orbital physics.

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