Comparing Hubbard parameters from linear-response theory and Hartree-Fock-based approach

Abstract

Density-functional theory with on-site U and inter-site V Hubbard corrections (DFT+U+V) is a powerful and accurate method for predicting various properties of transition-metal compounds. However, its accuracy depends critically on the values of these Hubbard parameters. Although they can be determined empirically, first-principles methods provide a more consistent and reliable approach; yet, their results can vary, and a comprehensive comparison between methods is still lacking. Here, we present a systematic comparison of two widely used approaches for computing U and V, namely linear-response theory (LRT) and the Hartree-Fock-based pseudohybrid functional formalism, applied to a representative set of oxides (MnO, NiO, CoO, FeO, BaTiO3, ZnO, and ZrO2). We find that for partially occupied transition-metal d states, these two methods yield consistent U values, but they differ for nearly empty or fully filled d shells. For O-2p states, LRT always predicts large U values (10 eV), whereas the pseudohybrid formalism produces system-dependent values depending on the level of localization and hybridization for the electronic states. Even larger differences are found for the inter-site V: the former predicts consistently small values (<1 eV), while the latter produces larger values (3 eV), reflecting its explicit dependence on relative charge redistribution. Our results show that while parallels between these two methods exist, they rely on distinct assumptions for determining U and V, leading to variations in predictions of material properties.

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