A wake-based correlate of swimming performance and foraging behavior in seven co-occurring jellyfish species
Abstract
It is generally accepted that animal–fluid interactions have shaped the evolution of animals that swim and fly. However, the functional ecological advantages associated with those adaptations are currently difficult to predict on the basis of measurements of the animal–fluid interactions. We report the identification of a robust, fluid dynamic correlate of distinct ecological functions in seven jellyfish species that represent a broad range of morphologies and foraging modes. Since the comparative study is based on properties of the vortex wake – specifically, a fluid dynamical concept called optimal vortex formation – and not on details of animal morphology or phylogeny, we propose that higher organisms can also be understood in terms of these fluid dynamic organizing principles. This enables a quantitative, physically based understanding of how alterations in the fluid dynamics of aquatic and aerial animals throughout their evolution can result in distinct ecological functions.
Additional Information
© 2010. Published by The Company of Biologists Ltd. Accepted 15 December 2009. First published online March 26, 2010. The authors gratefully acknowledge helpful suggestions from the reviewers and funding from the National Science Foundation (OCE-0727587 and OCE-0623508 to J.H.C.; OCE-0351398 and OCE-0623534 to S.P.C.; OCE-0623475 to J.O.D.) and the Office of Naval Research (N000140810654 and N000140810918).Attached Files
Published - Dabiri2010p7489J_Exp_Biol.pdf
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Additional details
- Eprint ID
- 17922
- Resolver ID
- CaltechAUTHORS:20100412-080852786
- NSF
- OCE-0727587
- NSF
- OCE-0623508
- NSF
- OCE-0351398
- NSF
- OCE-0623534
- NSF
- OCE-0623475
- Office of Naval Research
- N000140810654
- Office of Naval Research
- N000140810918
- Created
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2010-04-30Created from EPrint's datestamp field
- Updated
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2021-11-08Created from EPrint's last_modified field