Dynamics and phase behavior of metallo-dielectric rod-shaped microswimmers driven by alternating current electric field

Dynamics and phase behavior of metallo-dielectric rod-shaped microswimmers driven by alternating current electric field

The ability to move and self-organize in response to external stimuli is a fascinating feature of living active matter. Here, the metallo-dielectric rod-shaped microswimmers are shown to have a similar behavior in the presence of an AC electric field. The silica-copper Janus microrods were fabricate...

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Veröffentlicht in:Soft matter 2024-05, Vol.2 (19), p.3971-3979
Hauptverfasser: Panda, Suvendu Kumar, Debata, Srikanta, Kherani, Nomaan Alam, Singh, Dhruv Pratap
Format: Artikel
Sprache:eng
Schlagworte:
Alternating current
Aqueous solutions
Clustering
Electric field
Electric fields
Electrohydrodynamics
Electrophoresis
External stimuli
Metallography
Physical vapor deposition
Rods
Silica
Slip flow
Swimming
Swimming behavior
Torque
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Zusammenfassung:The ability to move and self-organize in response to external stimuli is a fascinating feature of living active matter. Here, the metallo-dielectric rod-shaped microswimmers are shown to have a similar behavior in the presence of an AC electric field. The silica-copper Janus microrods were fabricated using the physical vapor deposition-based glancing angle deposition technique (GLAD). When the aqueous solution of the microrods was under the influence of an external AC electric field, they were found to exhibit different phases such as clustering, swimming, and vertical standing in response to variation of the applied frequency. The swimming behavior (5-90 kHz) of the rods is attributed to the induced-charge electrophoresis (ICEP) phenomenon, whereas the dynamic clustering (
ISSN:1744-683X
1744-6848
DOI:10.1039/d4sm00206g