Revisiting LaMnO3: A density functional theory study

Abstract: Density functional theory (DFT) has been widely applied to a variety of realistic materials but often struggles to explain the properties of correlated systems. The DFT + U method, which introduces a Hubbard U correction to the DFT, has been instrumental in providing the treatment of systems such as transition metal oxide. The methodological details of DFT + U and their specifics on the electronic structures and magnetic properties of the correlated systems remain incompletely understood. In this study, taking the prototypical transition metal oxide system, LaMnO3, as an example, we systematically assess the performance of the two distinct DFT + U methods, spin-polarized DFT (SDFT + U) and spin-un-polarized DFT (CDFT + U). We found that while Coulomb U acts similarly for the two approaches, Hund JH plays a fundamentally different role, particularly in the determination of the magnetic phases. Our investigation shows the active role of Hund JH on the exchange splitting, leading to distinct magnetic ground configurations in the two methods. We further investigate the associated magnetic exchange interactions and compare our results with so-called beyond-DFT methods.