AI Article Synopsis
- The study combines computer simulations and analytical methods to explore how athermal particles behave in dense formations under self-propulsion.
- Increasing the persistence time of self-propulsion enhances local structure but leads to complex changes in long-term motion, initially speeding up and then slowing down.
- A new nonequilibrium microscopic theory is presented, providing insights into the observed dynamics and emphasizing the role of steady-state local velocity correlations in this context.
Article Abstract
We combine computer simulations and analytical theory to investigate the glassy dynamics in dense assemblies of athermal particles evolving under the sole influence of self-propulsion. Our simulations reveal that when the persistence time of the self-propulsion is increased, the local structure becomes more pronounced, whereas the long-time dynamics first accelerates and then slows down. We explain these surprising findings by constructing a nonequilibrium microscopic theory that yields nontrivial predictions for the glassy dynamics. These predictions are in qualitative agreement with the simulations and reveal the importance of steady-state correlations of the local velocities to the nonequilibrium dynamics of dense self-propelled particles.
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| http://dx.doi.org/10.1103/PhysRevE.91.062304 | DOI Listing |
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