News Release

Quest for jellyfish robot leads to discovery of bending rules for animal wing, fin tips

Peer-Reviewed Publication

Marine Biological Laboratory

<em>Aurelia aurita</em> (Moon Jellyfish)

image: Engineers are collaborating with biologists to replicate the jellyfish's efficient motion in a swimming robot. view more 

Credit: Brad Gemmell

WOODS HOLE, Mass. —A Navy-sponsored project to design a biologically inspired, swimming jellyfish robot has led scientists to the surprising discovery of common bending rules for the tips of wings, fins, flukes, mollusk feet, and other propulsors across a broad range of animal species.

The study, led by John H. Costello of Providence College and the Marine Biological Laboratory (MBL) in Woods Hole, where he is a visiting scientist, is published this week in Nature Communications.

By studying videos of 59 different animals—from fruit flies to humpback whales—propelling in steady-state motion through air or water, the team discovered that the animals' propulsors bend in a similar way at the tip, with a highly constrained and predictable range of characteristic movements. (Steady-state motion is continual, replicable cycles of propulsive motion, in contrast to rapid acceleration or deceleration.)

"We were interested in looking at how many animals use flexible margins (or tips) on their propulsors because we know in the jellyfish vehicle, propulsive proficiency improved by orders of magnitude when we put a passive, flexible, silicone margin around the [jellyfish] bell," Costello says. "The question for us was, how and why does flexibility increase thrust? And from an engineering standpoint, how do you incorporate flexibility into a design so it does increase thrust?"

The team looked at natural propulsors, which have had millions of years to evolve design efficiencies, for guidance with their models. "We found that the way the propulsors moved—the kinematics—seems to be selected for across this wide range of animals, rather than the material properties, such as feathers or scales, being key," Costello says. "Discovering these uniform bending characteristics has reoriented our search for understanding the advantages of flexibility in propulsion."

The paper's lead author, Kelsey N. Lucas, was an undergraduate advisee of co-author Sean Colin of Roger Williams University at the time of the study, and is now a graduate student at Harvard University. Colin is also an MBL visiting scientist and principal investigator with Costello on the Navy's jellyfish robot project.

"Flying and swimming animals have a much lower cost of transport (energy needed to move a mass a given distance) than present manmade designs of similar scale," Costello says. "That is part of our motivation for understanding biological design: Animals do it better."

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Citation:

Lucas KN, Johnson N, Beaulieu WT, Cathcart E, Tirrell G, Colin SP, Gemmell BJ, Dabiri, JO, Costello JH (2014) Bending rules for animal propulsion. Nature Comm. 5: 3293 DOI: 10.1038/ncomms4293

For background:

Built for Efficiency, Not Speed: Scientists Discover New Propulsive Mechanism in Jellyfish

Colin SP, Costello JH, Dabiri JO, Villanueva A, Blottman JB, Gemmell BJ, Priya S (2012) Biomimetic and Live Medusae Reveal the Mechanistic Advantages of a Flexible Bell Margin. PLOS One DOI: 10.1371/journal.pone.0048909

The Marine Biological Laboratory (MBL) is dedicated to scientific discovery and improving the human condition through research and education in biology, biomedicine, and environmental science. Founded in Woods Hole, Massachusetts, in 1888, the MBL is a private, nonprofit institution and an affiliate of the University of Chicago.


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