Lattice normal modes and electronic properties of the correlated metal LaNiO3

Abstract

We use density functional theory (DFT) calculations to study the lattice vibrations and electronic properties of the correlated metal LaNiO3. To characterize the rhombohedral to cubic structural phase transition of perovskite LaNiO3, we examine the evolution of the Raman-active phonon modes with temperature. We find that the A1g Raman mode, whose frequency is sensitive to the electronic band structure, is a useful signature to characterize the octahedral rotations in rhombohedral LaNiO3. We also study the importance of electron--electron correlation effects on the atomic structure with two approaches which go beyond the conventional band theory (local spin density approximation): the local spin density+Hubbard U method (LSDA+U) and hybrid exchange-correlation density functionals which include portions of exact Fock-exchange. We find the conventional LSDA accurately reproduces the delocalized nature of the valence states in LaNiO3 and gives the best structural and vibrational agreement to the available experimental data. Based on our calculations, we show that the electronic screening effect from the delocalized Ni 3d and O-2p states mitigate the electronic correlations of the d7 Ni cations, making LaNiO3 a weakly correlated metal.