Magnetic anisotropy energies and metal-insulator transitions in monolayers of α-RuCl3 and OsCl3 on graphene

Abstract

Transition metal thriclorides, with 4d or 5d electrons, are materials at the forefront of recent studies about the interplay of spin-orbit coupling and strong Coulomb interactions. Within our first-principles calculations (DFT+U+SOC) we study the effects of graphene on the electronic and magnetic properties of the monolayers of α-RuCl3 and OsCl3. Despite the spatially inhomogeneous n-type doping induced by graphene, we show that the occupancy of the upper Hubbard bands of MLs of and OsCl3 can be tuned through external electric fields, and allows the control of (i) metal-insulator transitions, and (ii) the magnetic easy-axis and anisotropy energies. Our findings point towards the tunning of electronic and magnetic properties of transition metal thriclorides monolayers by using graphene and external electronic fields.