Open AccessThermodynamics of the Bladderwort Feeding Strike—Suction Power from Elastic Energy Storage
Author(s) -
Otto van den Berg,
Krizma Singh,
Maxwell R. Hall,
M. Janneke Schwaner,
Ulrike K. Müller
Publication year - 2019
Publication title -
integrative and comparative biology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.328
H-Index - 123
eISSN - 1557-7023
pISSN - 1540-7063
DOI - 10.1093/icb/icz144
Subject(s) - suction , mechanics , reynolds number , mechanical energy , fish <actinopterygii> , range (aeronautics) , energy storage , work (physics) , energy budget , flow (mathematics) , environmental science , power (physics) , materials science , physics , thermodynamics , fishery , biology , turbulence , composite material
The carnivorous plant bladderwort exemplifies the use of accumulated elastic energy to power motion: respiration-driven pumps slowly load the walls of its suction traps with elastic energy (∼1 h). During a feeding strike, this energy is released suddenly to accelerate water (∼1 ms). However, due to the traps’ small size and concomitant low Reynolds number, a significant fraction of the stored energy may be dissipated as viscous friction. Such losses and the mechanical reversibility of Stokes flow are thought to degrade the feeding success of other suction feeders in this size range, such as larval fish. In contrast, triggered bladderwort traps are generally successful. By mapping the energy budget of a bladderwort feeding strike, we illustrate how this smallest of suction feeders can perform like an adult fish.
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