A Microfluidic Tool for Fine‐Tuning Motion of Soft Micromotors

A Microfluidic Tool for Fine‐Tuning Motion of Soft Micromotors

Microfluidics is an ideal tool for the design of self‐assembled micromotors. It allows for easy change of solutions, catalysts, and flow rates, which affect shape, structure, and motion of the resulting micromotors. A microfluidic tool generating aqueous‐two‐phase‐separating droplets of UV‐polymeriz...

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Bibliographic Details
Published in:Advanced functional materials Vol. 29; no. 44
Main Authors: Keller, Shauni, Hu, Guo Xun, Gherghina‐Tudor, Maria I., Teora, Serena P., Wilson, Daniela A.
Format: Journal Article
Language:English
Published: Hoboken Wiley Subscription Services, Inc 01-11-2019
Subjects:
aqueous‐two‐phase‐system
autonomous motion
bubble propulsion
Catalysts
Ethylene glycol
Flow velocity
Low molecular weights
Materials science
Microfluidics
Micromotors
Molecular weight
Nanoparticles
Pinning
Polysaccharides
Shape effects
Surface roughness
Trajectories
Tuning
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Summary:Microfluidics is an ideal tool for the design of self‐assembled micromotors. It allows for easy change of solutions, catalysts, and flow rates, which affect shape, structure, and motion of the resulting micromotors. A microfluidic tool generating aqueous‐two‐phase‐separating droplets of UV‐polymerizable poly(ethylene glycol)diacrylate (PEGDA) and an inert phase, salt, or polysaccharide, is utilized to fabricate asymmetric microbeads. Different molecular weights and branching of polysaccharides are used to study the effect on shape, surface roughness, and motion of the particles. The molecular weight of the polysaccharide determines the roughness of the motors inner surface. Smooth openings are obtained by low molecular weight dextran, while high surface roughness is obtained with a high molecular weight branched polysaccharide. Since roughness plays an important role in bubble pinning, it influences both speed and trajectory. Increasing speeds are obtained with increasing roughness and trajectories ranging from linear, circular to tumble‐and‐run depending on the nature of bubble pinning. This microfluidic tool allows for fine‐tuning shape, structure, and motion by easy change of solutions, catalysts, and flow rates. A microfluidic tool is utilized to design asymmetric, soft micromotors of different roughness. Since roughness plays an important role in bubble pinning, it influences both speed and trajectory. Increasing speeds are obtained with increasing roughness and trajectories ranging from linear, circular to tumble‐and‐run depending on the nature of bubble pinning.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201904889