Emergent single-species non-reciprocity from bistable chemical dynamics

TL;DR

This paper introduces a mechanism where bistable chemical reactions in colloids lead to emergent non-reciprocal interactions, enabling dynamic control over collective behaviors like swarming.

Contribution

It demonstrates how internal chemical bistability in colloids causes non-reciprocal interactions and emergent collective dynamics, a novel approach in active matter systems.

Findings

Colloids can switch between being chemical producers or consumers.

Non-reciprocal interactions lead to diverse collective behaviors.

Tuning parameters induce bifurcations and complex dynamics.

Abstract

The appearance of emergent symmetries in complex systems with components that can form composite units provides us with opportunities for design and control of exotic phase behaviour, for example by exploiting the dynamical symmetry breaking associated with them. We present a novel mechanism for the emergence of non-reciprocal interactions in a single-species suspension of chemically active colloids made out of semi-permeable vesicles, which encapsulate enzymes that catalyze a non-linear chemical reaction. Bistable chemical dynamics enables the colloidal reaction chamber to act as a net producer or consumer of a chemical, depending on the selected values of the chemical concentrations inside and around it. Since the internal chemical state of the colloid depends on the dynamic chemical concentrations rather than the material parameters, two identically produced colloids can present different effective chemical interactions within the same system upon responding to the corresponding gradients via diffusiophoresis. Furthermore, the colloids can spontaneously and reversibly switch between being effective consumers or producers. As a consequence, the colloids can dynamically switch between ignoring, attracting, repelling, and chasing each other, in a non-reciprocal manner. This flexibility can be exploited by manipulation of tuning parameters to induce bifurcations in the chemical dynamics, resulting in a robust control over the interaction motifs, and rich emergent dynamics such as spontaneous many-body polar swarming.