Fundamental Modes of Swimming Correspond to Fundamental Modes of Shape: Engineering I‐, U‐, and S‐Shaped Swimmers

Fundamental Modes of Swimming Correspond to Fundamental Modes of Shape: Engineering I‐, U‐, and S‐Shaped Swimmers

Hydrogels have received increased attention due to their biocompatible material properties, adjustable porosity, ease of functionalization, tuneable shape, and Young's moduli. Initial work has recognized the potential that conferring out‐of‐equilibrium properties to these on the microscale hold...

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Bibliographic Details
Published in:Advanced intelligent systems Vol. 3; no. 11
Main Authors: Sharan, Priyanka, Maslen, Charlie, Altunkeyik, Berk, Rehor, Ivan, Simmchen, Juliane, Montenegro-Johnson, Thomas D.
Format: Journal Article
Language:English
Published: Weinheim John Wiley & Sons, Inc 01-11-2021
Wiley
Subjects:
active matter
Asymmetry
Biocompatibility
Biomedical materials
bubble-driven micromotors
Bubbles
Catalase
Elastic buckling
Enzymes
Expulsion
Filaments
Growth models
Hydrogels
Material properties
microswimmers
Modulus of elasticity
Motility
Scanning electron microscopy
stop-flow lithography
Swimming
Symmetry
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Summary:Hydrogels have received increased attention due to their biocompatible material properties, adjustable porosity, ease of functionalization, tuneable shape, and Young's moduli. Initial work has recognized the potential that conferring out‐of‐equilibrium properties to these on the microscale holds and envisions a broad range of biomedical applications. Herein, a simple strategy to integrate multiple swimming modes into catalase‐propelled hydrogel bodies, produced via stop‐flow lithography (SFL), is presented and the different dynamics that result from bubble expulsion are studied. It is found that for “Saturn” filaments, with active poles and an inert midpiece, the fundamental swimming modes correspond to the first three fundamental shape modes that can be obtained by buckling elastic filaments, namely, I, U, and S‐shapes. Enzyme‐driven micromotors show different motion modes, depending on their shape: the zeroth shape mode (I) typically results in pumping, the first one (one bend, U) in translation, and the second one (two bends, S) in rotation.
ISSN:2640-4567
2640-4567
DOI:10.1002/aisy.202100068