Field-mediated active dynamical bonds
Abstract
Active matter systems typically exhibit a trade-off between structural robustness and dynamical freedom, limiting independent control over structure and motion. Here, we show that encoding interactions in a shared field overcomes this constraint, enabling continuous tuning between stable architectures and dynamically active states. Using droplets on a vibrated fluid bath as a minimal realization, we demonstrate that individually unstable units can collectively self-stabilize through field-mediated dynamical bonds. Arising from wavefield interference, these bonds form persistent, self-healing connections that preserve architecture while sustaining motion. Droplet size sets the symmetry of the interactions, with identical droplets forming rigid -like frameworks that enforce triangular packing, while smaller droplets enable -like coordination that supports higher-order symmetries. The resulting assemblies exhibit both stability and sustained collective dynamics, including spontaneous rotation and controlled migration. This work establishes a general route to programmable active matter in which shared fields reconcile structural robustness with dynamical freedom.
Cite
@article{arxiv.2604.09506,
title = {Field-mediated active dynamical bonds},
author = {Yuanmei Li and Rahil Valani},
journal= {arXiv preprint arXiv:2604.09506},
year = {2026}
}
Comments
9 pages, 5 figures