Proposal of a general scheme: valley polarization in antiferromagnetic bilayer systems

TL;DR

This paper proposes a universal method to induce valley polarization in antiferromagnetic bilayer systems, utilizing stacking techniques and symmetry operations, thereby advancing the field of antiferromagnetic valleytronics.

Contribution

The authors introduce a general stacking scheme to realize valley polarization in AFM bilayers, involving layer-locked hidden valley polarization and related phenomena, demonstrated through three material examples.

Findings

Demonstrated valley polarization in AFM bilayers using specific materials.

Revealed layer-locked hidden valley polarization and associated effects.

Proposed detection methods via out-of-plane electric fields.

Abstract

Superior to ferromagnetic (FM) valleytronics, antiferromagnetic (AFM) counterpart exhibits ultradense and ultrafast potential due to their intrinsic advantages of zero stray field, terahertz dynamics, and compensated moment of antiferromagnets. However, the physics of spontaneous valley polarization is mainly rooted in FM hexagonal lattices and is rarely used to explore the simultaneous spin and valley polarizations in AFM materials. Here, we propose a general stacking way to achieve valley polarization in AFM bilayer systems. The hexagonal ferrovalley material is used as the basic building unit, and then the space-inversion centrosymmetric bilayer system with interlayer AFM ordering is constructed by horizontal mirror and 2-fold rotational operations, which can exhibit spontaneous valley polarization. In this construction process, the rarely explored \textit{layer-locked hidden valley polarization}, hidden Berry curvature and layer Hall effect are involved, and an out-of-plane electric field can be used to detect hidden valley polarization and to realize layer-locked anomalous valley Hall effect. We use three examples to illustrate our proposal. Firstly, the Janus GdBrI is used to prove concepts and effects involved in our design process. Secondly, the $\mathrm{RuBr_2}$ is used to demonstrate other phenomena, including valley polarization transition and \textit{near-ideal quantum spin Hall insulator}. Finally, we use our design principles to understand the valley polarization of experimentally synthesized MnSe from a new perspective. Our works establish a robust general scheme to achieve valley polarization in AFM bilayer systems, thereby opening up new avenues for AFM valleytronics.