Abstract
We numerically investigate the propelled motions of a Janus particle in a periodically phase-separating binary fluid mixture. In this study, the surface of the particle tail prefers one of the binary fluid components and the particle head is neutral in the wettability. During the demixing period, the more wettable phase is selectively adsorbed to the particle tail. Growths of the adsorbed domains induce the hydrodynamic flow in the vicinity of the particle tail, and this asymmetric pumping flow drives the particle toward the particle head. During the mixing period, the particle motion almost ceases because the mixing primarily occurs via diffusion and the resulting hydrodynamic flow is negligibly small. Repeating this cycle unboundedly moves the Janus particle toward the head. The dependencies of the composition and the repeat frequency on the particle motion are discussed.
Highlights
Self-propelled motions of micro- and nano-particles have attracted much interest from a wide range of viewpoints
We proposed a possible mechanism of propelled motions of Janus particles in periodically phase-separating binary mixtures using numerical simulations
The particle speed depends on the solvent viscosity in symmetric mixtures; studying the in uences of the viscosity difference would be interesting
Summary
Self-propelled motions of micro- and nano-particles have attracted much interest from a wide range of viewpoints. We demonstrate a possible mechanism of spontaneous motions of a Janus particle in periodically phaseseparating mixtures. By continually varying the temperature or pressure slightly above and below the transition point, one can cause periodic processes of phase separation and mixing.[37,38,39,40] By resetting the binary mixtures to the one-phase state, we expected that we could continuously propel the particle. We examine this expectation by means of numerical simulations.
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