Sliding-induced ferrovalley polarization and possible antiferromagnetic half-metal in bilayer altermagnets
Xin Zhang, Shihao Zhang

TL;DR
This paper demonstrates that interlayer sliding in bilayer altermagnets can induce ferrovalley polarization and possibly lead to antiferromagnetic half-metallicity, offering new ways to control valley states without external fields.
Contribution
It introduces a method to achieve spontaneous valley degeneracy breaking via sliding in engineered bilayer altermagnets, revealing potential for novel valleytronic devices.
Findings
Sliding induces ferrovalley polarization in bilayer altermagnets.
Mo₂O₂O shows a valley splitting gap of ~0.31 eV, suitable for valley-spin devices.
Increasing atomic number difference enhances valley polarization.
Abstract
Altermagnets, a newly discovered class of materials, exhibit zero net magnetization while hosting spin-split electronic bands. However, monolayer altermagnets maintain degenerate band gaps at the high-symmetry X and Y points in the Brillouin zone, manifesting a paravalley phase characterized by unpolarized valley states. In this work, we demonstrate that spontaneously broken valley degeneracy can be achieved through interlayer sliding in engineered MAB and MAAB bilayer altermagnets by first-principles calculations and minimal microscopic model. We propose a promising route to achieve antiferromagnetic half-metal driven by sliding and emergent ferrovalley phase without applied electric field, which is realized in the VSSeO engineered bilayer. Our calculations also reveal that MoOO exhibits the largest valley splitting gap of ~0.31 eV, making it a promising…
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