Seminar on 27 October 2022

Academy of Sciences of the Czech Republic, Department of Spintronics and Nanoelectronics, Cukrovanícká 10, Praha
Spin-transfer torque in non-collinear antiferromagnetic junctions
at 14:00 in Seminar room F2

Ferromagnetic spin-vales and tunneling junctions are one of the most fundamental and important spintronics devices. Their functionality is based on two effects: the giant or tunneling magnetoresistance for electrical readout and the spin-transfer torque allowing for electrical switching. It has been predicted previously that the same functionality could be achieved with antiferromagnetic junctions, which would provide various advantages over ferromagnets, such as a much faster switching speed. However, these devices are very sensitive to disorder and have never been experimentally demonstrated [1]. Here we show that the key to obtaining robust spin-transfer torque and magnetoresistance in antiferromagnets is utilizing lower symmetry antiferromagnets, in which electrical current is spin-polarized [2,3]. We consider junctions composed of non-collinear antiferromagnets and find a spin-transfer torque and magnetoresistance with a magnitude and robustness against disorder comparable to ferromagnetic junctions [3]. Furthermore, our calculations reveal novel aspects of the torque in non-collinear junctions. In particular, we find that apart from the conventional spin-transfer torque, a novel self-generated torque appears. This torque is similar to a spin-orbit torque but has a non-relativistic origin. We also find that a torque appears for any configuration of the junction, in contrast to ferromagnetic junctions where the torque vanishes in the parallel or antiparallel configurations. [1] J. Železný et al., Nature Physics 14, 220–228 (2018)
[2] J. Železný et al., PRL 119, 187204 (2017)
[3] S. Ghosh et al., PRL 128, 097702 (2022)