Trilayer multi-orbital models of La4Ni3O10

Abstract

Recently, the discovery of superconductivity in Ruddlesden-Popper (RP) La4Ni3O10 under pressure has further expanded the realm of nickelate-based superconductor family. In this paper, we performed a first-principle study of La4Ni3O10 for both P21/a phase at ambient pressure and I4/mmm phase at high pressure, with U=0, 3.5\ eV. Our results confirmed the characteristic upward shift of Ni-dz2 bonding band under pressure. Moreover, our analysis of electronic spectrum and orbital occupancy unveil the dynamic mechanism of electronic reconstructions under pressure, embedded in a critical dual effect. Based on our results, we further proposed a trilayer two-orbital model by performing Wannier downfolding on Ni-eg orbitals. Our model reveals four Fermi surface sheets with α,β,β,γ pockets, bearing resemblance to that of bilayer La3Ni2O7. According to the model, our calculated spin susceptibility under random phase approximation shows that dx2-y2 orbital is also important for the magnetic fluctuation in RP series. Finally, a high energy sixteen-orbital model with direct dp,pp hoppings is proposed, which implies that La4Ni3O10 also lies in charge-transfer picture within Zaanen-Sawatzky-Allen scheme. Our exposition of electronic reconstructions and multi-orbital models shed light on theoretical electronic correlation study and experimental exploration of lower pressure superconductor in RP series.