Interfacially-Adsorbed Particles Enhance the Self-Propulsion of Oil Droplets in Aqueous Surfactant

28 June 2021, Version 3
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Understanding the chemo-mechanical mechanisms that direct the motion of self-propulsive colloids is important for the development of active materials and exploration of dynamic, collective phenomena. Here, we demonstrate that the adsorption of solid particles on the surface of solubilizing oil droplets can significantly enhance the droplets’ self-propulsion speeds. We investigate the relationship between the self-propulsion of bromodecane oil droplets containing silica particles of varying concentration in Triton X-100 surfactant, noting up to order of magnitude increases in propulsion speeds. Using fluorescently labeled silica, we observe packing of the particles at the oil-water interfaces of the rear pole of the moving droplets. For bromodecane oil droplets in Triton X-100, the highest droplet speeds were achieved at approximately 40% particle surface coverage of the droplet interface. We find particle-assisted propulsion enhancement in ionic surfactants and different oil droplet compositions as well, demonstrating the breadth of this effect. While a precise mechanism for the propulsion enhancement remains unclear, the simple addition of silica particles to droplet oil-water interfaces provides a straightforward route to tune active droplet dynamics.

Keywords

emulsion
droplets
active matter

Supplementary materials

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Video S1
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Transmission optical microscopy video of bromodecane droplets with 0.5 wt% H13L particles in 0.1 wt% Triton X-100. Video is played back in 6x speed.
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Video S2
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Fluorescence microscopy video of bromodecane droplets containing 2 wt% fluorescent particles dispersed 0.5 wt% Triton X-100 immediately after preparation by vortex mixing and added to an imaging chamber containing surfactant. The particles are initially dispersed inside the droplets, but over time, the particles accumulate at the droplet surface and aggregate in a cap at the rear pole of the droplet. Droplets begin to move when the interfacial particle cap forms. Video is played back in 2x speed.
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Video S3
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Fluorescence microscopy video of bromodecane droplets with 2 wt% fluorescent particles dispersed in 0.5 wt% Triton X-100. Video is played back in 2x speed.
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Video S7
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Bright field transmission optical microcopy video of bromodecane droplets with 0.5 wt% fluorescent particles in 2.5 wt% CTAB. Video is played back at 2x speed.
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Video S4
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Side-view transmission optical microscopy video of a bromodecane droplet in 0.1 wt% Triton X-100, without interfacially-adsorbed particles. Particles in the continuous phase are tracer particles used to visualize the flow around the droplet. The solubilizing droplet pumps fluid from top to bottom, and the drop does not move laterally. Video is played back at 3x speed.
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Video S5
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Side-view transmission optical microscopy video of a bromodecane droplet, with 1 wt% fluorescent particles, in 0.1 wt% Triton X-100. The droplet self-propels with the particle cap oriented perpendicular to the substrate. Occasionally the droplet translates perpendicular to the imaging plane so continuous refocusing is needed to follow the droplet motion. Video is played back at 3x speed.
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Video S6
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Side-view transmission optical microscopy video of a bromodecane droplet, with 1 wt% fluorescent particles, in 0.1 wt% Triton X-100. While similar to Video S5, here a droplet is seen where the cap orients largely parallel to the substrate, causing fluid pumping from top to bottom and preventing lateral motion. The rotation of the particle cap is critical to the droplet lateral translation. Video is played back at 3x speed.
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Supporting Information
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Supporting information
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