Abstract
The fate of (micro)plastic particles in the open ocean is controlled by physical and biological processes. Here, we model the effects of biofouling on the subsurface vertical distribution of spherical, virtual plastic particles with radii of 0.01–1 mm. For the physics, four vertical velocity terms are included: advection, wind-driven mixing, tidally induced mixing, and the sinking velocity of the biofouled particle. For the biology, we simulate the attachment, growth and loss of algae on particles. We track 10,000 particles for one year in three different regions with distinct biological and physical properties: the low productivity region of the North Pacific Subtropical Gyre, the high productivity region of the Equatorial Pacific and the high mixing region of the Southern Ocean. The growth of biofilm mass in the euphotic zone and loss of mass below the euphotic zone result in the oscillatory behaviour of particles, where the larger (0.1–1.0 mm) particles have much shorter average oscillation lengths (< 10 days; 90th percentile) than the smaller (0.01–0.1 mm) particles (up to 130 days; 90th percentile). A subsurface maximum concentration occurs just below the mixed layer depth (around 30 m) in the Equatorial Pacific, which is most pronounced for larger particles (0.1–1.0 mm). This occurs since particles become neutrally buoyant when the processes affecting the settling velocity of the particle and the motion of the ocean are in equilibrium. Seasonal effects in the subtropical gyre result in particles sinking below the mixed layer depth only during spring blooms, but otherwise remaining within the mixed layer. The strong winds and deepest average mixed layer depth in the Southern Ocean (400 m) result in the deepest redistribution of particles (> 5000 m). Our results show that the vertical movement of particles is mainly affected by physical (wind-induced mixing) processes within the mixed layer and biological (biofilm) dynamics below the mixed layer. Furthermore, positively buoyant particles with radii of 0.01–1.0 mm can sink far below the euphotic zone and mixed layer in regions with high near-surface mixing or high biological activity. This work can easily be coupled to other models to simulate open-ocean biofouling dynamics, in order to reach a better understanding of where ocean (micro)plastic ends up.
Highlights
Observations have shown that plastic ends up everywhere in the ocean, from the Arctic (Cózar et al, 2017), to the Mariana Trench (Chiba et al, 2018; Peng et al, 2018)
We focus on three regions in this study, which have different physical and biological profiles: (1) the Equatorial Pacific (EqPac) from -4.5◦ to 4.5◦ N and 139◦ to 148◦ W, (2) the North Pacific Subtropical Gyre (NPSG) from 23◦ to 32◦ N and 134◦ 80 to 143◦ W and (3) the Southern Ocean (SO) from -53◦ to -62◦ N and 106◦ to 115◦ W (Fig. 1)
In all three regions and for both size classes the average mixed layer depth (MLD) seems to affect the vertical distribution of particles more than the average euphotic zone depth (EZD)
Summary
Observations have shown that plastic ends up everywhere in the ocean, from the Arctic (Cózar et al, 2017), to the Mariana Trench (Chiba et al, 2018; Peng et al, 2018). Observations down to 2000 m traversing the North Pacific Subtropical Gyre (Egger et al, 2020) show that the highest concentration of 0.5 to 50 mm-sized particles is at the surface and a power-law decline occurs with depth (with surface concentrations up to four orders of magnitude larger than at deeper depths) In both the Monterey Bay, 25 km offshore (Choy et al, 2019), and in three regions in the East Indian 35 Ocean (Li et al, 2020), a subsurface maximum concentration of 0.1 to 5 mm-sized particles has been observed around 200 m (just below the average mixed layer depth in the Monterey Bay). These studies show that vertical plastic concentration profiles vary spatially, and we investigate the physical and biological mechanisms that affect such variation
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