Meta-Generalized Gradient Approximation Made Magnetic
Jacques K. Desmarais, Alessandro Erba, Giovanni Vignale, Stefano Pittalis
Abstract
The Jacob's ladder of density functional theory (DFT) proposes the compelling view that by extending the form of successful approximations-being guided by exact conditions and selected (least empirical) norms-upper rungs will do better than the lower, thus allowing to balance accuracy and computational effort. Meta-generalized gradient approximations (MGGAs) belong to the last rung of the semilocal approximations before hybridization with nonlocal wave function theories. Among the MGGAs, the strongly constrained and appropriately normed approximation (SCAN) greatly improves upon GGAs from the lower rung. But the over magnetized solutions of SCAN make GGAs more reliable for magnetism. Here, we provide a solution that satisfies the most pressing desiderata for a density functional approximations for ferromagnetic, antiferromagnetic and noncollinear states. The approach is available in an implementation in the crystal electronic structure package.