Self-Propulsion Mechanism of Active Janus Particles in Near-Critical Binary Mixtures
Publication date
2015-10-29
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Abstract
Gold-capped Janus particles immersed in a near-critical binary mixture can be propelled using illumination. We employ a nonisothermal diffuse interface approach to investigate the self-propulsion mechanism of a single colloid. We attribute the motion to body forces at the edges of a micronsized droplet that nucleates around the particle. Thus, the often-used concept of a surface velocity cannot account for the self-propulsion. The particle's swimming velocity is related to the droplet shape and size, which is determined by a so-called critical isotherm. Two distinct swimming regimes exist, depending on whether the droplet partially or completely covers the particle. Interestingly, the dependence of the swimming velocity on temperature is nonmonotonic in both regimes.
Keywords
COLLOIDAL PARTICLES, LIGHT-SCATTERING, SHEAR VISCOSITY, PECLET NUMBERS, INTERFACE, FLUID, TRANSPORT, MOTION, CARGO, Taverne
Citation
Samin, S & van Roij, R 2015, 'Self-Propulsion Mechanism of Active Janus Particles in Near-Critical Binary Mixtures', Physical Review Letters, vol. 115, no. 18, 188305, pp. 1-5. https://doi.org/10.1103/PhysRevLett.115.188305