Guiding Self-Assembly of Active Colloids by Temporal Modulation of Activity

Self-organization phenomena in ensembles of self-propelled particles open pathways to the synthesis of new dynamic states not accessible by traditional equilibrium processes. The challenge is to develop a set of principles that facilitate the control and manipulation of emergent active states. Here, we report that dielectric rolling colloids energized by a pulsating electric field self-organize into alternating square lattices with a lattice constant controlled by the parameters of the field. We combine experiments and simulations to examine spatiotemporal properties of the emergent collective patterns and investigate the underlying dynamics of the self-organization.We reveal the resistance of the dynamic lattices to compression and expansion stresses leading to a hysteretic behavior of the lattice constant. The general mechanism of pattern synthesis and control in active ensembles via temporal modulation of activity can be applied to other active colloidal systems.

Automated summary

Self-organization phenomena in ensembles of self-propelled particles provide pathways for synthesizing new dynamic states. By controlling and manipulating principles, dielectric rolling colloids energized by a pulsating electric field can self-organize into alternating square lattices. The resistive and hysteresis behaviors of the dynamic lattices to compression and expansion stresses are uncovered. This mechanism can be applied to other active colloidal systems.