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RESEARCH PRODUCT
Assembly and Speed in Ion-Exchange-Based Modular Phoretic Microswimmers.
Ran NiuAlexander ReinmüllerThomas PalbergJulian WeberDenis Botinsubject
Materials scienceIon exchangebusiness.industryNanotechnologymacromolecular substances02 engineering and technologySurfaces and InterfacesMechanicsModular design010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciences0104 chemical sciencesModeling and simulationSwimming speedElectrochemistryGeneral Materials ScienceBoundary value problem0210 nano-technologyGeometric modelingbusinessSpectroscopydescription
We report an experimental study on ion-exchange-based modular microswimmers in low-salt water. Cationic ion-exchange particles and passive cargo particles assemble into self-propelling complexes, showing self-propulsion at speeds of several micrometers per second over extended distances and times. We quantify the assembly and speed of the complexes for different combinations of ion-exchange particles and cargo particles, substrate types, salt types and concentrations, and cell geometries. Irrespective of the experimental boundary conditions, we observe a regular development of the assembly shape with increasing number of cargo. Moreover, the swimming speed increases stepwise upon increasing the number of cargo and then saturates at a maximum speed, indicating the active role of cargo in modular swimming. We propose a geometric model of self-assembly to describe the experimental observations in a qualitative way. Our study also provides some constraints for future theoretical modeling and simulation.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-03-28 | Langmuir : the ACS journal of surfaces and colloids |