Gyroscopic stabilization minimizes drag on Ruellia ciliatiflora seeds

Gyroscopic stabilization minimizes drag on Ruellia ciliatiflora seeds

Fruits of Ruellia ciliatiflora (Acanthaceae) explosively launch small (2.5 mm diameter × 0.46 mm thick), disc-shaped seeds at velocities over 15 m s−1, reaching distances of up to 7 m. Through high-speed video analysis, we observe that seeds fly with extraordinary backspin of up to 1660 Hz. By model...

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Veröffentlicht in:Journal of the Royal Society interface 2018-03, Vol.15 (140), p.20170901-20170901
Hauptverfasser: Cooper, Eric S., Mosher, Molly A., Cross, Carolyn M., Whitaker, Dwight L.
Format: Artikel
Sprache:eng
Schlagworte:
Acanthaceae
Aerodynamics
Ballistichory
Dispersal
Dispersion
Drag
Energy costs
Flight
Gyroscopic Stabilization
High speed
High-Speed Video
Life Sciences–Physics interface
Ruellia ciliatiflora
Seed Dispersal
Seeds
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Beschreibung
Zusammenfassung:Fruits of Ruellia ciliatiflora (Acanthaceae) explosively launch small (2.5 mm diameter × 0.46 mm thick), disc-shaped seeds at velocities over 15 m s−1, reaching distances of up to 7 m. Through high-speed video analysis, we observe that seeds fly with extraordinary backspin of up to 1660 Hz. By modelling the seeds as spinning discs, we show that flying with backspin is stable against gyroscopic precession. This stable backspin orientation minimizes the frontal area during flight, decreasing drag force on the seeds and thus increasing dispersal distance. From high-speed video of the seeds' flight, we experimentally determine drag forces that are 40% less than those calculated for a sphere of the same volume and density. This reduces the energy costs for seed dispersal by up to a factor of five.
ISSN:1742-5689
1742-5662
DOI:10.1098/rsif.2017.0901