Finding the 'sweet spot': Marine animals save energy by swimming at optimal depths

16 Dec 2024, 20:00 by Swansea University

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Little penguins travel beneath the zone of highest wave drag close to the surface. Many air-breathing marine vertebrates optimize their swim depth when transiting and not feeding, traveling just deep enough to avoid wave creation on the surface. Credit: Phillip Island Nature Parks.

Researchers from Swansea and Deakin Universities have found that marine animals across mammals, birds and reptiles swim at similar relative depths when traveling and not feeding to save energy.

Dr. Kimberley Stokes, Professor Graeme Hays and Dr. Nicole Esteban from Swansea and Deakin Universities, led research across six institutes in five countries comparing the swim depths of several sea turtle, penguin and whale species. All traveled at around three body depths from the surface in order to swim in the "sweet spot" that minimizes wave formation at the surface and vertical distance traveled.

Some semi-aquatic animals, such as mink, swim at the surface where wave generation is a major source of wasted energy. However, for marine birds, mammals and reptiles traveling great distances over their lifetimes, adaptation to minimize the energetic cost of transport is expected, particularly on long journeys.

It has long been known that additional drag from wave creation minimizes once a traveling object is at depths greater than three times its diameter, but it was hard to compare with travel depths of wild animals due to tracking limitations.

In this study published in Proceedings of the National Academy of Sciences, near surface swim depths were recorded to within 1.5 centimeters in little penguin and loggerhead turtles, along with motion data and video footage from animal-borne cameras.

Like many air-breathing marine megafauna, green turtles optimize their swim depth during migration to minimize the cost of transport, traveling at around three body-depths beneath the surface in order to avoid creating waves while maximizing horizontal distance traveled. Credit: R. D. and B. S. Kirkby.

This was compared with satellite tracking data for long-distance migrations in green turtles and data from other studies on penguins and whales. It was found that these animals swim at optimal depths predicted by physics when either "commuting" to a foraging patch in the wild or migrating over longer distances while not feeding.

Swansea University's Dr. Kimberley Stokes, lead author of the study said, "There are, of course, examples where animal swim depth is driven by other factors, such as searching for prey, but it was exciting to find that all published examples of non-foraging air-breathing marine animals followed the predicted pattern.

"This has rarely been recorded because of the difficulty in retrieving depth data from animals that migrate over large distances, so it was great to find enough examples to show a common relationship between swim depth and body size from animals across the size spectrum from 30 cm to about 20 m in length."

More information: Esteban, Nicole, Optimization of swim depth across diverse taxa during horizontal travel, Proceedings of the National Academy of Sciences (2024). DOI: 10.1073/pnas.2413768121. doi.org/10.1073/pnas.2413768121

Journal information: Proceedings of the National Academy of Sciences

Provided by Swansea University