Electronic structure trends in La2RNi2O7 (R= Pr, Nd, Sm) from first-principles

Abstract

The discovery of superconductivity in bilayer La3Ni2O7 under pressure has sparked tremendous attention on Ruddlesden-Popper (RP) nickelates. Recently, a higher superconducting transition temperature of 96 K was reported in Sm-doped La3Ni2O7 single crystals at 22 GPa. Motivated by this experimental observation, we systematically explore the crystal structure and electronic properties of La3Ni2O7 doped with different rare-earth elements in comparison to the undoped counterpart. As expected due to the effect of chemical pressure, we find that the volume of La2RNi2O7 (R= Pr, Nd, Sm) progressively decreases with doping from Pr to Sm. We further find a pressure-induced structural transition to tetragonal symmetry that approximately coincides with the emergence of superconductivity in all cases. This transition is characterized by the emergence of flat dz2 bands at the Fermi level in the electronic structure. Despite subtle distinctions in the electronic structure between undoped and R-doped La3Ni2O7, an increase in the dominant planar hopping is obtained as the R size decreases. In contrast, the out-of-plane hopping decreases (in spite of the c lattice constant compression), due to the decrease in the apical Ni-O rocksalt bond length. Our findings provide further microscopic insights into the effects of R-doping in the electronic structure of RP nickelate superconductors in connection to Tc.