📝 SummarXiv

Abstract

Altermagnetism is characterized by non-relativistic spin splitting and zero total magnetic moments. In this work, intrinsic antiferromagnetic half-metallic and topological phases were discovered within the ferrovalley states of sliding bilayer altermagnets. We construct the bilayer system by utilizing altermagnet monolayers with a small bandgap. The inter-layer hopping phenomenon leads to a reduction in bandgaps, and sliding engineering induces ferrovalley states. Taking the V$_2$OSSe system for example, first-principles calculations indicate that the spin-dependent inter-layer hopping in the ferrovalley state ensures a direct gap in one valley (one spin channel) and band inversion in the other valley (opposite spin channel), which is manifested as an intrinsic antiferromagnetic half-metal. The microscopic model and effective Hamiltonian employed in this research confirm the universal spin-dependent inter-layer hopping in the sliding altermagnet bilayer. Further calculations imply the existence of Chern insulator and gapless surface states in the sliding altermagnet bilayer. Adjusting the sliding direction can achieve the transition between different half-metals with conducting electrons of different spins, accompanied by the switching of gapless surface states of opposite spins. This research lays a foundation for the potential applications of intrinsic antiferromagnetic half-metals and topological phases in spintronics.