Effect of swimming mode on shielding of odor traces in turbulence

TL;DR

This study uses direct numerical simulations to show how marine swimmers alter odor plume shapes in turbulence, affecting detection likelihood and revealing differences between swimmer types.

Contribution

It demonstrates how swimming dynamics influence odor transport and introduces the concept of olfactory shielding, highlighting differences between pusher and puller swimmers.

Findings

Swimmers increase odor mixing through flow fluctuations and circulation.

Olfactory shielding reduces detection probability at large distances.

Puller swimmers are more effective at shielding than pushers.

Abstract

Marine organisms manipulate their surrounding flow through their swimming dynamics, which affects the transport of their own odor cues. We demonstrate by direct numerical simulations how a group of swimmers, moving at intermediate Reynolds numbers, immersed in a turbulent flow, alter the shape of the odor plume they release in the water. Odor mixing is enhanced by increased velocity fluctuations and a swimmer-induced flow circulation that widens the odor plume at close range while speeding up dilution of the chemical trace. Beyond a short-range increase in the likelihood of being detected, swimming considerably reduces detections with effects that can persist at distances on the order of ten times the size of the group or more. We find that pullerlike swimmers are more effective at olfactory shielding than pusherlike swimmers. We trace this difference back to the dynamics at the swimmer location, which tends to trap odor at the source for pushers and to dilute it for pullers. Olfactory shielding is robust to changes in the conditions, and is more pronounced for weak turbulent Reynolds numbers and large swimmer Reynolds numbers. Our results suggest that olfactory shielding may play a role in the emergence of different swimming modalities by marine organisms.