(TKP2021-NVA-19) Funder: Ministry for Innovation and Technology
Self-assembly functionalizes active constituents to perform rhythmic activities. Here,
our results show that the capillary-Marangoni interaction of irregularly moving gel
beads develops complex patterns at the air-liquid interface. The collective behavior
of the self-assembled structures exhibits breathing dynamics, polygonal oscillating
rings, and cluster synchrony of chains. Interestingly, the trapping of soft particles
generates relay synchronization of a rotor. Swarming of clusters is found to form
rhythmic shrinking and expanding multiple-ring patterns. The development of self-organized
spatiotemporal patterns of our active gel system provides a new way of creating collective
oscillations.
