High resistive unipolar-electrical and fs-optical switching in a single-layer antiferromagnetic memory.

In established memory concepts, information is encoded in the atomic structure, electronic charge, or magnetic moment orientation. Here we introduce a distinct principle of information encoding in antiferromagnets which provides an unparalleled set of characteristics and functionalities. We demonstrate unipolar reversible switching between memory states controlled by current amplitude in an elementary two-terminal device geometry. We show that resistive readout signals in our devices made of a single-layer magnetic film approach 100%, and that the switching characteristics are precisely reproducible and insensitive to magnetic field. Moreover, our devices can integrate memory with analog and logic functions mimicking spiking neuromorphic components. Apart from electrical switching, we demonstrate optical writing down to a single, 100fs long laser pulse. The high-resistance states decay following a universal stretched-exponential relaxation law, supporting a picture of the underlying microscopic mechanism in which information is encoded in complex disordered magnetic nano-textures with macroscopic time stability in the dipolar-field free antiferromagnets.