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BiocalcificationInduces the Preferential Settlingof Small Buoyant Microplastics in Freshwater
Summary
Researchers found that biocalcification processes involving Microcystis aeruginosa and calcium ions promote the preferential settling of small buoyant microplastics in freshwater, with incubation experiments revealing how algal-induced mineral precipitation accelerates vertical transport of particles that would otherwise remain suspended.
The vertical transport of microplastics (MPs) in freshwater is poorly understood. In this study, the effects of biocalcification on the settling behavior of buoyant MPs in the presence of Microcystis aeruginosa and Ca2+ were investigated via incubation experiments. Here, we show that the formation of biogenic calcite on the surface of MPs resulted in an increase in density and, subsequently, the settling of MPs, with its effect varying significantly with the size and aging of MPs. Specifically, biogenic calcite preferentially facilitated the sinking of smaller MPs compared to larger ones, mainly due to their different adsorption affinities for extracellular polymeric substances (EPS), which provide nucleation sites for calcite. Notably, aging further enhanced this size-dependent settling of MPs, which was primarily attributable to differences in the selective binding of macromolecules in EPS. Compared to the pristine MPs, the aged ones tend to acquire more polar macromolecules from EPS, which resulted in greater complexation interactions between the MPs and Ca2+ and consequently increased biogenic calcite precipitation and enhanced settling of MPs. The findings of this study highlight the importance of biogenic calcite-mediated settling of MPs in freshwater environments.
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