Picosecond transfer from short-term to long-term memory in analog antiferromagnetic memory device

Experiments in materials with a compensated ordering of magnetic moments have demonstrated a potential for approaching the thermodynamic limit of the fastest and least-dissipative operation of a digital memory bit. In addition, these materials are very promising for a construction of energy-efficient analog devices with neuromorphic functionalities, which are inspired by computing-in-memory capabilities of the human brain. In this paper, we report on experimental separation of switching-related and heat-related resistance signal dynamics in memory devices microfabricated from CuMnAs antiferromagnetic metal. We show that the memory variable multilevel resistance can be used as a long-term memory (LTM), lasting up to minutes at room temperature. In addition, ultrafast reflectivity change and heat dissipation from nanoscale-thickness CuMnAs films, taking place on picosecond to hundreds of nanoseconds time scales, can be used as a short-term memory (STM). Information about input stimuli, represented by femtosecond laser pulses, can be transferred from STM to LTM after rehearsals at picosecond to nanosecond times in these memory devices, where information can be retrieved at times up to 10^15 longer than the input pulse duration. Our results open a route towards ultra-fast low-power implementations of spiking neuron and synapse functionalities using a resistive analog antiferromagnetic memory.
Comment: 21 pages, 4 figures