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Entrainment dominates the interaction of microalgae with micron-sized objects
Summary
Researchers studied how swimming microalgae (Chlamydomonas reinhardtii) physically move nearby microparticles through the water, finding that rare close-encounter events — where the algae directly sweep up and carry particles — dominate over normal diffusion. This finding helps explain how microplastic particles and other tiny debris may be transported by living organisms in aquatic environments.
The incessant activity of swimming microorganisms has a direct physical effect on surrounding microscopic objects, leading to enhanced diffusion far beyond the level of Brownian motion with possible influences on the spatial distribution of non-motile planktonic species and particulate drifters. Here we study in detail the effect of eukaryotic flagellates, represented by the green microalga Chlamydomonas reinhardtii, on microparticles. Macro- and microscopic experiments reveal that microorganism-colloid interactions are dominated by rare close encounters leading to large displacements through direct entrainment. Simulations and theoretical modelling show that the ensuing particle dynamics can be understood in terms of a simple jump-diffusion process, combining standard diffusion with Poisson-distributed jumps. This heterogeneous dynamics is likely to depend on generic features of the near-field of swimming microorganisms with front-mounted flagella.
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