Ionic Screening and Dissociation are Crucial for Understanding Chemical Self-Propulsion in Water

TL;DR

This paper demonstrates that ionic reactions and screening effects are essential for accurately modeling chemical self-propulsion in water, revealing their significant impact on swimmer behavior and speed.

Contribution

It introduces a continuum theory that incorporates bulk ionic reactions and screening effects, highlighting their influence on chemical swimmer dynamics and speed.

Findings

Bulk reactions enable electrophoretic propulsion of neutral swimmers.

Reactions significantly alter predicted swimmer speeds, up to tenfold.

Inverse relationship between swimmer size and speed explained by screening effects.

Abstract

Water is a polar solvent and hence supports the bulk dissociation of itself and its solutes into ions, and the re-association of these ions into neutral molecules in a dynamic equilibrium, e.g., ${\rm H_2O_2}\leftrightharpoons {\rm H^+~+~HO_2^-}$. Using continuum theory, we study the influence of these reactions on the self-propulsion of colloids driven by surface chemical reactions (chemical swimmers) in aqueous solution. The association-dissociation reactions are here shown to have a strong influence on the swimmers' behaviour, and must therefore be included in future modelling. In particular, such bulk reactions permit charged swimmers to propel electrophoretically even if all species involved in the surface reactions are neutral. The bulk reactions also significantly modify the predicted speed of chemical swimmers propelled by ionic currents, by up to an order of magnitude. For swimmers whose surface reactions produce both anions and cations (ionic self-diffusiophoresis), the bulk reactions produce an additional reactive screening length, analogous to the Debye length in electrostatics. This in turn leads to an inverse relationship between swimmer radius and swimming speed, which could provide an alternative explanation for recent experimental observations on Pt-polystyrene Janus swimmers [S. Ebbens et al., Phys. Rev. E 85, 020401 (2012)]. We also use our continuum theory to investigate the effect of the Debye screening length itself, going beyond the infinitely thin limit approximation used by previous analytical theories. We identify significant departures from this limiting behavior for micron-sized swimmers under typical experimental conditions, and find that the limiting behavior fails entirely for nanoscale swimmers.