Magnetism in 2D BN1-xOx and B1-xSixN: polarized itinerant and local electrons

Abstract

We use density functional theory based first-principles methods to study the magnetism in a 2D hexagonal BN sheet induced by the different concentrations of oxygen and silicon atoms substituting for nitrogen (ON) and boron (SiB) respectively. We demonstrate the possible formation of three distinct phases based on the magnetization energy calculated self-consistently for the ferromagnetic (MEFM) and antiferromagnetic (MEAFM) states, i.e. the paramagnetic phase with MEFM=MEAFM, the ferromagnetic phase with MEFM>MEAFM and finally the polarized itinerant electrons with finite MEFM but zero MEAFM. While the ON system was found to exist in all three phases, no tendency towards the formation of the polarized itinerant electrons was observed for the SiB system though the existence of the other two phases was ascertained. The different behavior of these two systems is associated with the diverse features in the magnetization energy as a function of the oxygen and silicon concentrations. Finally, the robustness of the polarized itinerant electron phase is also discussed with respect to the O substitute atom distributions and the applied strains to the system.