First-principles study of electronic and magnetic properties of self-intercalated van der Waals magnet Cr3Ge2Te6

Abstract

Self-intercalated van der Waals magnets, characterized by self-intercalating native atoms into van der Waals layered structures with intrinsic magnetism, exhibit a variety of novel physical properties. Here, using first-principles calculations and Monte Carlo simulations, we report a self-intercalated van der Waals ferromagnet, Cr3Ge2Te6, which has a high Curie temperature of 492 K. We find that Cr3Ge2Te6 is nearly half-metallic with a spin polarization reaching up to 90.9%. Due to the ferromagnetism and strong spin-orbit coupling effect in Cr3Ge2Te6, a large anomalous Hall conductivity of 138 -1 cm-1 and 305 -1 cm-1 can be realized when its magnetization is along its magnetic easy axis and hard axis, respectively. By doping electrons (holes) into Cr3Ge2Te6, these anomalous Hall conductivities can be increased up to 318 -1 cm-1 (648 -1 cm-1). Interestingly, a 5-layer Cr3Ge2Te6 thin film retains the room-temperature ferromagnetism with a higher spin polarization and larger anomalous Hall conductivity. Our work demonstrates that Cr3Ge2Te6 is a novel room-temperature self-intercalated ferromagnet with high spin polarization and large anomalous Hall conductivity, offering great opportunities for designing nano-scale electronic devices.