Abstract
Physonect siphonophores are colonial cnidarians that are pervasive predators in many neritic and oceanic ecosystems. Physonects employ multiple, clonal medusan individuals, termed nectophores, to propel an aggregate colony. Here we show that developmental differences between clonal nectophores of the physonect Nanomia bijuga produce a division of labour in thrust and torque production that controls direction and magnitude of whole-colony swimming. Although smaller and less powerful, the position of young nectophores near the apex of the nectosome allows them to dominate torque production for turning, whereas older, larger and more powerful individuals near the base of the nectosome contribute predominantly to forward thrust production. The patterns we describe offer insight into the biomechanical success of an ecologically important and widespread colonial animal group, but, more broadly, provide basic physical understanding of a natural solution to multi-engine organization that may contribute to the expanding field of underwater-distributed propulsion vehicle design.
Highlights
Physonect siphonophores are colonial cnidarians that are pervasive predators in many neritic and oceanic ecosystems
Physonect siphonophores are a group of colonial cnidarians that possess the most complex colony-level organization of all animals[9,10] and have evolved a highly sophisticated multi-jet propulsion system
We show that developmental differences between nectophores of the physonect N. bijuga produce a division of labour in thrust and torque production by individuals within the nectosome
Summary
Physonect siphonophores are colonial cnidarians that are pervasive predators in many neritic and oceanic ecosystems. We show that developmental differences between clonal nectophores of the physonect Nanomia bijuga produce a division of labour in thrust and torque production that controls direction and magnitude of whole-colony swimming. We show that developmental differences between nectophores of the physonect N. bijuga produce a division of labour in thrust and torque production by individuals within the nectosome. These patterns permit all members of the colony—from younger, smaller individuals to older, larger individuals—to make important contributions to the propulsion and manoeuvring traits that are critical for the success of N. bijuga in their natural environment. The integration of different individuals into a natural solution of multi-engine organization may contribute to the expanding field of underwater-distributed propulsion vehicle design
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