An experimental implementation of a two-sphere swimmer at low Reynolds numbers

Oliver Silverberg; Brent Hosoume; Nikhil Trivedi; Connor Tisch; Daniel Plascencia; Matthew Holmes; On Shun Pak; Emre Araci

An experimental implementation of a two-sphere swimmer at low Reynolds numbers

ORAL

Abstract

Locomotion at low Reynolds numbers encounters stringent constraints due to the dominance of viscous over inertial forces. Various elegant designs have been proposed to escape from the constraints of the scallop theorem and generate self-propulsion. In this talk, we present a macroscopic experimental implementation of the “Pushmepullyou” swimmer (J. E. Avron, O. Kenneth, D. H. Oaknin, New J. Phys., 7, 234, 2005), which consists of a pair of expandable spheres connected by an extensible link. We characterized the propulsion performance of the swimmer in the low Reynolds number regime with the use of highly viscous silicone oil and compared the results with theoretical predictions.

Nov. 26, 2019, 9:16 AM – Nov. 26, 2019, 9:29 AM

Authors

Oliver Silverberg
- Mechanical Engineering, Santa Clara University
Brent Hosoume
- Mechanical Engineering, Santa Clara University
Nikhil Trivedi
- Mechanical Engineering, Santa Clara University
Connor Tisch
- Mechanical Engineering, Santa Clara University
Daniel Plascencia
- Bioengineering, Santa Clara University
Matthew Holmes
- Mechanical Engineering, Santa Clara University
On Shun Pak
- Mechanical Engineering, Santa Clara University
- Department of Mechanical Engineering, Santa Clara University
- Santa Clara University
Emre Araci
- Bioengineering, Santa Clara University