Add to ORKGThe widely employed DFT+U formalism is known to give rise to many self-consistent yet energetically distinct solutions in correlated systems, which can be highly problematic for reliably predicting the thermodynamic and physical properties of such materials. Here we study this phenomenon in the bulk materials UO_2, CoO, and NiO, and in a CeO_2 surface. We show that the following factors affect which self-consistent solution a DFT+U calculation reaches: (i) the magnitude of U; (ii) initial correlated orbital occupations; (iii) lattice geometry; (iv) whether lattice symmetry is enforced on the charge density; and (v) even electronic mixing parameters. These various solutions may differ in total energy by hundreds of meV per atom, so identifyi...
International audienceOver the last decade, a significant amount of work has been devoted to point d...
The quantitative prediction of electronic properties in correlated materials requires simulations wi...
This chapter introduces the Hubbard model and its applicability as a corrective tool for accurate mo...
The widely employed DFT+U formalism is known to give rise to many self-consistent yet energetically ...
We present in full detail a newly developed formalism enabling density functional perturbation theor...
Many people in the materials science and solid-state community are familiar with the acronym “DFT+U....
In investigations on electronic structures of correlated materials such as transition-metal oxides, ...
Except for small molecules, it is impossible to solve many electrons systems without imposing severe...
We present an approach to the DFT + U method (density functional theory + Hubbard model) within whic...
The electronic correlations in materials drive a variety of fascinating phenomena from magnetism to ...
In electronic structure methods based on the correction of approximate density-functional theory (DF...
We implemented the popular Hubbard density-functional theory + U (DFT+U) method in its spherically a...
First-principles modeling of systems with localized d states is currently a great challenge in conde...
The defect relaxation volumes obtained from density-functional theory (DFT) calculations of charged ...
Semilocal density-functional theory (DFT) methods exhibit significant errors for the phase diagrams ...
International audienceOver the last decade, a significant amount of work has been devoted to point d...
The quantitative prediction of electronic properties in correlated materials requires simulations wi...
This chapter introduces the Hubbard model and its applicability as a corrective tool for accurate mo...
The widely employed DFT+U formalism is known to give rise to many self-consistent yet energetically ...
We present in full detail a newly developed formalism enabling density functional perturbation theor...
Many people in the materials science and solid-state community are familiar with the acronym “DFT+U....
In investigations on electronic structures of correlated materials such as transition-metal oxides, ...
Except for small molecules, it is impossible to solve many electrons systems without imposing severe...
We present an approach to the DFT + U method (density functional theory + Hubbard model) within whic...
The electronic correlations in materials drive a variety of fascinating phenomena from magnetism to ...
In electronic structure methods based on the correction of approximate density-functional theory (DF...
We implemented the popular Hubbard density-functional theory + U (DFT+U) method in its spherically a...
First-principles modeling of systems with localized d states is currently a great challenge in conde...
The defect relaxation volumes obtained from density-functional theory (DFT) calculations of charged ...
Semilocal density-functional theory (DFT) methods exhibit significant errors for the phase diagrams ...
International audienceOver the last decade, a significant amount of work has been devoted to point d...
The quantitative prediction of electronic properties in correlated materials requires simulations wi...
This chapter introduces the Hubbard model and its applicability as a corrective tool for accurate mo...