Magnetism, symmetry and spin transport in van der Waals layered systems

Spintronic properties of layered materials combining magnetism and strong spin-orbit coupling can be tailored by proper optimization of chemical interactions and structural material symmetries. This Review draws a route to achieving best performing material design for reaching the upper limit of spin-orbit torque efficiency in switching magnetization. The discovery of an ever-increasing family of atomic layered magnetic materials, together with the already established vast catalogue of strong spin-orbit coupling and topological systems, calls for some guiding principles to tailor and optimize novel spin transport and optical properties at their interfaces. Here, we focus on the latest developments in both fields that have brought them closer together and make them ripe for future fruitful synergy. After outlining fundamentals on van der Waals magnetism and spin-orbit coupling effects, we discuss how their coexistence, manipulation and competition could ultimately establish new ways to engineer robust spin textures and drive the generation and dynamics of spin current and magnetization switching in 2D-materials-based van der Waals heterostructures. Grounding our analysis on existing experimental results and theoretical considerations, we draw a prospective analysis about how intertwined magnetism and spin-orbit torque phenomena combine at interfaces with well-defined symmetries and how this dictates the nature and figures of merit of spin-orbit torque and angular momentum transfer. This will serve as a guiding role in designing future non-volatile memory devices that utilize the unique properties of 2D materials with the spin degree of freedom.

Automated summary

This review focuses on the spintronic properties of layered materials and emphasizes the importance of optimizing chemical interactions and material symmetries to achieve the best performing material design for spin-orbit torque efficiency.