A Laboratory Study of the Effects of Size, Density, and Shape on the Wave-Induced Transport of Floating Marine Litter
R. Calvert (The University of Edinburgh, Environmental Fluid Mechanics)
A. Peytavin (The Ocean Cleanup Foundation)
Y. Pham (The Ocean Cleanup Foundation)
A. Duhamel (The Ocean Cleanup Foundation)
JPPM van der Zanden (Maritime Research Institute Netherlands (MARIN))
S. M. van Essen (Maritime Research Institute Netherlands (MARIN), TU Delft - Ship Hydromechanics)
B. Sainte-Rose (The Ocean Cleanup Foundation)
Ton van den Bremer (Environmental Fluid Mechanics, University of Oxford)
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Abstract
Floating marine litter is transported by several mechanisms, including surface waves. In studies of marine litter transport, the wave-induced drift is set to be equal to the Stokes drift, corresponding to the Lagrangian-mean wave-induced drift of an infinitesimally small tracer. Large-scale experiments are used to show how the wave-induced drift of objects of finite size depends on their size, density, and shape. We observe increases in drift of 95% compared to Stokes drift for discs with diameters of 13% of the wavelength, up to 23% for spheres with diameters of 3% of the wavelength, whereas drift is reduced for objects that become submerged such as nets. We investigate what these findings may imply for the transport of plastic pollution in realistic wave conditions and we predict an increase in wave-induced drift for (very) large plastic pollution objects. The different extrapolation techniques we explore to make this prediction exhibit a large range of uncertainty.
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