Electronic structure and magnetic tendencies of trilayer La4Ni3O10 under pressure: structural transition, molecular orbitals, and layer differentiation

Abstract

Motivated by the recent observation of superconductivity in the pressurized trilayer La4Ni3O10 Ruddlesden-Popper (RP) nickelate, we explore its structural, electronic, and magnetic properties as a function of hydrostatic pressure from first-principles calculations. We find that in both the bilayer and trilayer nickelates, an orthorhombic(monoclinic)-to-tetragonal transition under pressure takes place concomitantly with the onset of superconductivity. The electronic structure of La4Ni3O10 can be understood using a molecular trimer basis wherein n molecular subbands arise as the dz2 orbitals hybridize strongly along the c-axis within the trilayer. The magnetic tendencies indicate that the ground state at ambient pressure is formed by nonmagnetic inner planes and stripe-ordered outer planes that are antiferromagnetically coupled along the c axis, resulting in an unusual , 0, stacking that is consistent with the spin density wave model suggested by neutron diffraction. Such a state is destabilized by the pressures wherein superconductivity arises. Despite the presence of dz2 states at the Fermi level, the dx2-y2 orbitals also play a key role in the electronic structure of La4Ni3O10. This active role of the dx2-y2 states in the low-energy physics of the trilayer RP nickelate, together with the distinct electronic behavior of inner and outer planes, resembles the physics of multilayer cuprates.