Front-back asymmetry controls the impact of viscoelasticity on helical swimming

TL;DR

This study investigates how front-back asymmetry in helical swimmers influences the effect of viscoelastic fluids on their propulsion, demonstrating that geometry determines whether viscoelasticity enhances, reduces, or does not affect swimming speed.

Contribution

It reveals that swimmer geometry, specifically front-back asymmetry, controls viscoelastic effects on propulsion, supported by experimental data and theoretical modeling.

Findings

Viscoelasticity can increase swimming speed up to five times.

Viscoelasticity can decrease swimming speed up to five times.

Impact of viscoelasticity depends on swimmer geometry and asymmetry.

Abstract

We conduct experiments with force-free magnetically-driven rigid helical swimmers in Newtonian and viscoelastic (Boger) fluids. By varying the sizes of the swimmer body and its helical tail, we show that the impact of viscoelasticity strongly depends on the swimmer geometry: it can lead to a significant increase of the swimming speed (up to a factor of five), a similar decrease (also up to a factor of five) or it can have approximately no impact. Analysis of our data along with theoretical modeling shows that the influence of viscoelasticity on helical propulsion is controlled by a snowman-like effect, previously reported for dumbbell swimmers, wherein the front-back asymmetry of the swimmer leads to a non-Newtonian elastic force that can either favor or hinder locomotion.