Interplay between magnetism and charge instabilities in layered NbSe2

Abstract

Using ab initio methods based on density functional theory, the electronic and magnetic structure of layered hexagonal NbSe2 is studied. In the case of single-layer NbSe2 it is found that, for all the functionals considered, the magnetic solution is lower in energy than the non-magnetic solution. The magnetic ground-state is ferrimagnetic with a magnetic moment of 1.09 μB at the Nb atoms and a magnetic moment of 0.05 μB, in the opposite direction, at the Se atoms. Our calculations show that single-layer NbSe2 does not display a charge density wave instability unless a graphene layer is considered as a substrate. Then, two kinds of 3×3 charge density waves are found, which are observed in our STM experiments. This suggest that the driving force of charge instabilities in NbSe2 differ in bulk and in the single-layer limit. Our work sets magnetism into play in this highly-correlated 2D material, which is crucial to understand the formation mechanisms of 2D superconductivity and charge density wave order.