Memory formation in dense persistent active matter
Abstract
Protocol-dependent states in structural glasses can encode a disordered, yet retrievable memory. While training such materials is typically done via a global drive, such as external shear, in dense active matter the driving is instead local and spatio-temporally correlated. Here we focus on the impact of such spatial correlation on memory formation. We investigate the mechanical response of a dense amorphous packing of athermal particles, subject to an oscillatory quasistatic driving with a tunable spatial correlation, akin to the instantaneous driving pattern in active matter. We find that the capacity to encode memory can be rendered comparable upon a proper rescaling on the spatial correlation, whereas the efficiency in memory formation increases with motion cooperativity.
Cite
@article{arxiv.2403.11701,
title = {Memory formation in dense persistent active matter},
author = {Elisabeth Agoritsas and Peter K. Morse},
journal= {arXiv preprint arXiv:2403.11701},
year = {2024}
}