Active Sinking Particles: Sessile Suspension Feeders significantly alter the Flow and Transport to Sinking Aggregates

Abstract

AbstractSinking or sedimentation of biological aggregates plays a critical role in carbon sequestration in the ocean and in vertical material fluxes in waste-water treatment plants. In both these contexts, the sinking aggregates are “active,” since they are biological hot-spots and are densely colonized by microorganisms including bacteria and sessile protists, some of which generate feeding currents. However, the effect of these feeding currents on the sinking rates, trajectories, and mass transfer to these “active sinking particles,” has not previously been studied. Here we use a novel scale-free vertical-tracking microscope (a.k.a. Gravity Machine, Krishnamurthy et al. “Scale-free vertical tracking microscopy.” Nature Methods (2020)) to follow model sinking aggregates (agar spheres) with attached protists (Vorticella convallaria), sinking over long distances while simultaneously measuring local flows. We find that activity due to attached Vorticella cause substantial changes to the flow around aggregates in a dynamic manner and reshape mass transport boundary layers. Further, we find that activity-mediated local flows along with sinking significantly changes how aggregates interact with the water-column at larger scales by modifying the encounter and plume cross-sections and by inducing sustained aggregate rotations. In this way our work suggests an important role of biological activity in understanding the growth, degradation, composition and sinking speeds of aggregates with consequences for predicting vertical material fluxes in marine, freshwater and man-made environments.1Significance StatementSinking aggregates are a critical part of aquatic ecosystems. Plentiful sinking aggregates account for the majority of carbon sequestration in the oceans. These aggregates are densely colonized by microorganisms, including many that generate feeding currents. Utilizing a novel instrument for high resolution imaging of sinking particles, we demonstrate that these feeding currents significantly change how water flows near the aggregates. We show that these changes in flow are likely to affect aquatic system processes, including aggregation rates, degradation rates, sinking speeds, and aggregate composition. Our work provides a starting point for exploring the larger-scale implications of attached organisms on these system processes, which, in turn, are critical for understanding carbon sequestration in the oceans or efficiency in waste-water treatment plants.