They are the largest fish species in the ocean but the majestic gliding motion of the whale shark is, scientists argue, an astonishing feat of mathematics and energy conservation. In new research published today in Functional Ecology, marine scientists reveal how these massive sharks use geometry to enhance their natural negative buoyancy and stay afloat.
For most animals movement is crucial for survival, both for finding food and for evading predators. However, movement costs substantial amounts of energy and while this is true of land based animals it is even more complex for birds and marine animals which travel in three dimensions. Unsurprisingly this has a profound impact on their movement patterns.
“The key factor for animal movement is travel speed, which governs how much energy an animal uses, the distance it will travel and how often resources are encountered,” said lead author Adrian Gleiss from Swansea University. “However, oceanic animals not only have to consider their travel speed, but also how vertical movement will affect their energy expenditure, which changes the whole perspective.”
For the past four years, Gleiss, Rory Wilson (Swansea University) and Brad Norman (ECOCEAN Inc. and Murdoch University) have led an international team to investigate the movements of whale sharks (Rhincodon typus) at Ningaloo Reef in Western Australia. They attached animal-borne motion sensors (accelerometers) to the free-swimming whale sharks to measure their swimming activity and vertical movement, which allowed them to quantify the energetic cost of vertical movement.
The team’s data revealed that whale sharks are able to glide without investing energy into movement when descending, but they had to beat their tails when they ascended. This occurs because sharks, unlike many fish, have negative buoyancy.
Also, the steeper the sharks ascended, the harder they had to beat their tail and the more energy they had to invest. The whale sharks displayed two broad movement modes — one consisting of shallow ascent angles, which minimise the energetic cost of moving in the horizontal, while a second characteristic of steeper ascent angles, optimized the energetic cost of vertical movement.
“These results demonstrate how geometry plays a crucial role in movement strategies for animals moving in 3-dimensions,” Gleiss said. “This use of negative buoyancy may play a large part in oceanic sharks being able to locate and travel between scarce and unpredictable food sources efficiently.
Brad Norman said: “The work at Ningaloo Reef is enabling us to solve some of the mysteries surrounding this threatened shark, especially understanding behaviour while these animals are out of the peering eyes of researchers. This technology has great potential and we’re only beginning to harness its power.”