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Predictable Gate-Field Control of Spin in Altermagnets with Spin-Layer Coupling

Run‐Wu Zhang, Chaoxi Cui, Runze Li, Jingyi Duan, Lei Li, Zhi‐Ming Yu, Yugui Yao

2024Physical Review Letters130 citationsDOI

Abstract

Spintronics, a technology harnessing electron spin for information transmission, offers a promising avenue to surpass the limitations of conventional electronic devices. While the spin directly interacts with the magnetic field, its control through the electric field is generally more practical, and has become a focal point in the field. Here, we propose a mechanism to realize static and almost uniform effective magnetic field by gate-electric field. Our method employs two-dimensional altermagnets with valley-mediated spin-layer coupling (SLC), in which electronic states display valley-contrasted spin and layer polarization. For the low-energy valley electrons, a uniform gate field is approximately identical to a uniform magnetic field, leading to predictable control of spin. Through symmetry analysis and ab initio calculations, we predict altermagnetic monolayer Ca(CoN)_{2} and its family materials as potential candidates hosting SLC. We show that an almost uniform magnetic field (B_{z}) indeed is generated by gate field (E_{z}) in Ca(CoN)_{2} with B_{z}∝E_{z} in a wide range, and B_{z} reaches as high as about 10^{3} T when E_{z}=0.2 eV/Å. Furthermore, owing to the clean band structure and SLC, one can achieve perfect and switchable spin and valley currents and significant tunneling magnetoresistance in Ca(CoN)_{2} solely using the gate field. Our work provides new opportunities to generate predictable control of spin and design spintronic devices that can be controlled by purely electric means.

Topics & Concepts

Spin (aerodynamics)Coupling (piping)Condensed matter physicsField (mathematics)Layer (electronics)PhysicsMaterials scienceNanotechnologyThermodynamicsPure mathematicsMetallurgyMathematicsMagnetic properties of thin filmsMagnetic and transport properties of perovskites and related materialsAdvanced Condensed Matter Physics