A large anomalous Hall effect and Weyl nodes in bulk FeNi3: a density functional theory study

Abstract

In this work, we report the study of electronic structure, magnetism, and the existence of Weyl nodes in a pristine bulk FeNi3, a member of Fe-Ni inver alloy compounds, known as good metal catalysts with high activity and stability for water splitting for a very long time. Our observation of Weyl points in the bulk FeNi3 may lead to a new technology to design highly efficient topological catalysts. While the previous literature PhysRev.97.304 mainly focused on the thermal and catalytic properties of FeNi3 we report the interplay of Fe d-Ni d hybridization and spin-orbit coupling give rise to the ferromagnetic Weyl nodes in the bulk FeNi3. Our study shows that the ground state of the bulk FeNi3 is a Weyl metal with a large number of Weyl nodes at the Fermi energy away from high-symmetry k-points. Furthermore, we predict a large intrinsic anomalous Hall conductivity of about 10000~S/m at the ground state. In addition, we show the existence of Weyl nodes along the high symmetry k-points ~0.2eV above and ~0.05eV below self-consistent Fermi level that may be achieved either by the electron or hole doping, or by external perturbation. In this article, FeNi3 has been studied to explore this scenario using first-principles density functional theory and subsequent Wannier90-based tight-binding method. Furthermore, we report the existence of two types of Weyl cones, type-I and type-II, ~0.2eV above the Fermi level. Our report provides a realistic material to further explore the intrinsic properties related to Weyl cones, and the spintronic applications.