Hydro-chemical interactions in dilute phoretic suspensions: from individual particle properties to collective organization

TL;DR

This paper investigates how individual particle properties influence collective organization in dilute suspensions of Janus phoretic colloids, revealing the roles of chemical signaling and fluid flows through modeling and simulations.

Contribution

It adapts a kinetic model linking particle design to collective behavior and analyzes the interplay of chemical and hydrodynamic interactions in pattern formation.

Findings

Chemical signaling promotes density patterns.

Fluid flows inhibit pattern formation.

Self-propulsion induces wave-like dynamics.

Abstract

Janus phoretic colloids (JPs) self-propel as a result of self-generated chemical gradients and exhibit spontaneous nontrivial dynamics within phoretic suspensions, on length scales much larger than the microscopic swimmer size. Such collective dynamics arise from the competition of (i) the self-propulsion velocity of the particles, (ii) the attractive/repulsive chemically-mediated interactions between particles and (iii) the flow disturbance they introduce in the surrounding medium. These three ingredients are directly determined by the shape and physico-chemical properties of the colloids' surface. Owing to such link, we adapt a recent and popular kinetic model for dilute suspensions of chemically-active JPs where the particles' far-field hydrodynamic and chemical signatures are intrinsically linked and explicitly determined by the design properties. Using linear stability analysis, we show that self-propulsion can induce a wave-selective mechanism for certain particles' configurations consistent with experimental observations. Numerical simulations of the complete kinetic model are further performed to analyze the relative importance of chemical and hydrodynamic interactions in the nonlinear dynamics. Our results show that regular patterns in the particle density are promoted by chemical signaling but prevented by the strong fluid flows generated collectively by the polarized particles, regardless of their chemotactic or antichemotactic nature (i.e. for both puller and pusher swimmers).