Abstract
We demonstrate that an all-antiferromagnetic tunnel junction with current perpendicular to the plane geometry can be used as an efficient spintronics device with potential high frequency operation. By using state-of-the-art density functional theory combined with quantum transport, we show that the N\'eel vector of the electrodes can be manipulated by spin-transfer torque. This is staggered over the two different magnetic sublattices and can generate dynamics and switching. At the same time the different magnetization states of the junction can be read by standard tunnelling magnetoresistance. Calculations are performed for CuMnAs$|$GaP$|$CuMnAs junctions with different surface terminations between the anti-ferromagnetic CuMnAs electrodes and the insulating GaP spacer. In particular we find that the torque remains staggered regardless of the termination, while the magnetoresistance depends on the microscopic details of the interface.
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