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Reciprocal swimming in viscoelastic granular hydrogels

Hongyi Xiao, Jing Wang, Achim Sack, Ralf Stannarius, Thorsten Pöschel
April 27, 2026
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Research Abstract & Technology Focus

We experimentally study a scallop-like swimmer with reciprocally flapping wings in a nearly frictionless, cohesive granular medium consisting of hydrogel spheres. Significant locomotion is found when the swimmer’s flapping frequency matches the inverse relaxation time of the material. Remarkably, the swimmer moves in the opposite direction compared with its motion in a cohesion-free granular material of hard plastic spheres. At higher or lower frequencies, we observe no motion of the swimmer, apart from a short initial transient phase. X-ray radiograms reveal that the wing motions create low-density zones, which in turn give rise to a hysteresis in drag and propulsion forces. This time-dependent effect, combined with the swimmer’s inertia, accounts for locomotion at intermediate frequencies.
Viscoelasticity Mechanics Materials science Hysteresis Drag Transient (computer programming)
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What is the core focus of the research titled 'Reciprocal swimming in viscoelastic granular hydrogels'?

This literature focuses on: We experimentally study a scallop-like swimmer with reciprocally flapping wings in a nearly frictionless, cohesive granular medium consisting of hydrogel spheres. Significant locomotion is found when the swimmer’s flapping frequency matches the in...

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Yes, highly correlated activity was mapped. An entry titled 'A Semi‐Interpenetrating Poly(Ionic Liquid) Network‐Driven Low Hysteresis and Transparent Hydrogel as a Self‐Powered Multifunctional Sensor' discusses this: AbstractConductive hydrogels are gaining significant attention as promising candidates for the fabrication materials for flexible electronics. Neve...

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