Spin-current generation by electrical means is among the core phenomena driving the field of spintronics. Using ab initio calculations we show that a room-temperature metallic collinear antiferro-magnet RuO2 allows for highly efficient spin-current generation, arising from anisotropically spin-split bands with conserved up and down spins along the Neel vector axis.
The zero net moment antiferromagnet acts as an electrical spin splitter with a 34 degrees propagation angle between spin-up and spin-down currents. The corresponding spin conductivity is a factor of 3 larger than the record value from a survey of 20 000 nonmagnetic spin-Hall materials.
We propose a versatile spin-splitter-torque concept circumventing limitations of spin-transfer and spin-orbit torques in present magnetic memory devices.