Harbor seal vibrissa morphology suppresses vortex-induced vibrations

peer reviewed Harbor seals (Phoca vitulina) often live in dark and turbid waters, where their mystacial vibrissae, or whiskers, play an important role in orientation. Besides detecting and discriminating objects by direct touch, harbor seals use their whiskers to analyze water movements, for example...

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Bibliographic Details
Published in:Journal of Experimental Biology
Main Authors: Hanke, Wolf, Witte, Mathias, Miersch, Lars, Brede, Martin, Oeffner, Johannes, Michael, Mark, Hanke, Frederike, Leder, Alfred, Dehnhardt, Guido
Other Authors: University of Rostock
Format: Article in Journal/Newspaper
Language:English
Published: 2010
Subjects:
harbor seal
vibrissae
CFD
PIV
hydrodynamics
pinniped
Life sciences
Sciences du vivant
Phoca vitulina
Online Access:https://orbilu.uni.lu/handle/10993/11729
https://orbilu.uni.lu/bitstream/10993/11729/1/No_File.pdf
https://doi.org/10.1242/jeb.043216
Description
Summary:peer reviewed Harbor seals (Phoca vitulina) often live in dark and turbid waters, where their mystacial vibrissae, or whiskers, play an important role in orientation. Besides detecting and discriminating objects by direct touch, harbor seals use their whiskers to analyze water movements, for example those generated by prey fish or by conspecifics. Even the weak water movements left behind by objects that have passed by earlier can be sensed and followed accurately (hydrodynamic trail following). While scanning the water for these hydrodynamic signals at a swimming speed in the order of meters per second, the seal keeps its long and flexible whiskers in an abducted position, largely perpendicular to the swimming direction. Remarkably, the whiskers of harbor seals possess a specialized undulated surface structure, the function of which was, up to now, unknown. Here, we show that this structure effectively changes the vortex street behind the whiskers and reduces the vibrations that would otherwise be induced by the shedding of vortices from the whiskers (vortex-induced vibrations). Using force measurements, flow measurements and numerical simulations, we find that the dynamic forces on harbor seal whiskers are, by at least an order of magnitude, lower than those on sea lion (Zalophus californianus) whiskers, which do not share the undulated structure. The results are discussed in the light of pinniped sensory biology and potential biomimetic applications.

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