Spinning and corkscrewing of oceanic macroplankton revealed through in situ imaging

Authors

Kelly R. Sutherland, Oregon Institute of Marine Biology
Alejandro Damian-Serrano, Oregon Institute of Marine Biology
Kevin T. Du Clos, Louisiana Universities Marine Consortium
Brad J. Gemmell, University of South Florida, Tampa
Sean Colin, Roger Williams UniversityFollow
John H. Costello, Marine Biological Laboratory

Document Type

Article

Publication Title

Science Advances

Publication Date

5-17-2024

Abstract

Helical motion is prevalent in nature and has been shown to confer stability and efficiency in microorganisms. However, the mechanics of helical locomotion in larger organisms (>1 centimeter) remain unknown. In the open ocean, we observed the chain forming salp, Iasis cylindrica, swimming in helices. Three-dimensional imaging showed that helicity derives from torque production by zooids oriented at an oblique orientation relative to the chain axis. Colonies can spin both clockwise and counterclockwise and longer chains (>10 zooids) transition from spinning around a linear axis to a helical swimming path. Propulsive jets are non-interacting and directed at a small angle relative to the axis of motion, thus maximizing thrust while minimizing destructive interactions. Our integrated approach reveals the biomechanical advantages of distributed propulsion and macroscale helical movement.

Volume

10

Issue

20

DOI

10.1126/sciadv.adm9511

Recommended Citation

Sutherland, K., Damian-Serrano, A., Du Clos, K., Gemmell, B., Colin, S., & Costello, J. (2024). Spinning and corkscrewing of oceanic macroplankton revealed through in situ imaging. Science Advances, 10 (20) https://doi.org/10.1126/sciadv.adm9511

E-ISSN

23752548