We propose to measure time-reversal symmetry breaking in altermagnetic heterostructures incorporating CrSb and the Dirac semimetal PtTe2. These heterostructures exhibit a switchable anomalous Hall effect near room-temperature in conjunction with vanishingly small net magnetzation, and are consequently extremely promising for low-energy, high-efficiency memory applications. PNR is critical to understanding the origin of this effect and differentiating between magnetic proximity effects and altermagnetic spin accumulation.

We propose to measure time-reversal symmetry breaking in altermagnetic heterostructures incorporating CrSb and the Dirac semimetal PtTe2. These heterostructures exhibit a switchable anomalous Hall effect near room-temperature in conjunction with vanishingly small net magnetzation, and are consequently extremely promising for low-energy, high-efficiency memory applications. PNR is critical to understanding the origin of this effect and differentiating between magnetic proximity effects and altermagnetic spin accumulation.

This project has a chance of unambiguously demonstrating spin-orbit torque induced switching for a typical perpendicular antiferromagnetic (AFM) material whose structure is simple and colinear. This experiment not only confirms the feasibility of using SOT to control magnetism of AFM but also clearly rules out other thermal artefacts by high Rxy signal-to-noise ratio and the typical SOT behaviors under external fields. This experiment can advance the development of antiferromagnetic spintronics and memory devices.

This project has a chance of unambiguously demonstrating spin-orbit torque induced switching for a typical perpendicular antiferromagnetic (AFM) material whose structure is simple and colinear. This experiment not only confirms the feasibility of using SOT to control magnetism of AFM but also clearly rules out other thermal artefacts by high Rxy signal-to-noise ratio and the typical SOT behaviors under external fields. This experiment can advance the development of antiferromagnetic spintronics and memory devices.