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Rethinking sinking: Imaging flow fields of natural marine aggregates to infer porosity-dependent changes in sinking velocity and carbon flux

2023 2 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 30 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Cora Hörstmann, Hans‐Peter Grossart Cora Hörstmann, Clara M. Flintrop, Clara M. Flintrop, Clara M. Flintrop, Morten Hvitfeldt Iversen, Morten Hvitfeldt Iversen, Hans‐Peter Grossart Hans‐Peter Grossart Morten Hvitfeldt Iversen, Soeren Ahmerkamp, Nasrollah Moradi, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Isabell Klawonn, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Xosé Antón Álvarez‐Salgado, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Cora Hörstmann, Jöran März, Cora Hörstmann, Jöran März, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Cora Hörstmann, Morten Hvitfeldt Iversen, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Morten Hvitfeldt Iversen, Cora Hörstmann, Hans‐Peter Grossart Javier Arı́stegui, Rainer Kiko, Rainer Kiko, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Arzhang Khalili, Hans‐Peter Grossart Hans‐Peter Grossart Morten Hvitfeldt Iversen, Hans‐Peter Grossart Morten Hvitfeldt Iversen, Hans‐Peter Grossart Xosé Antón Álvarez‐Salgado, Rainer Kiko, Javier Arı́stegui, Morten Hvitfeldt Iversen, Morten Hvitfeldt Iversen, Morten Hvitfeldt Iversen, Morten Hvitfeldt Iversen, Morten Hvitfeldt Iversen, Hans‐Peter Grossart Hans‐Peter Grossart Hans‐Peter Grossart Rainer Kiko, Hans‐Peter Grossart Hans‐Peter Grossart

Summary

Using particle image velocimetry on 81 marine aggregates, researchers found that small aggregates (below 500 µm) have higher density and lower porosity than large ones, leading to faster sinking and greater carbon transport per unit volume, with small aggregates contributing 40–70% of total vertical carbon flux. The study focuses on marine carbon cycling and does not directly address microplastic research.

Abstract The marine biological carbon pump is mainly driven by the interplay between aggregate sinking velocity and remineralization. Sinking velocity of natural marine aggregates is not routinely measured but often calculated using Stokes’ law, which does not consider size-dependent changes in porosity. We analyzed the flow fields around 81 in situ -formed aggregates using Particle Image Velocimetry (PIV) to determine the factors controlling aggregate settling. Using an independently derived scaling of porosity with size, we predicted the sinking velocity of laboratory-formed and in situ -formed aggregates with known densities. Small aggregates (<500 µm) have relatively lower porosities than large aggregates, and their increased compactness and density leads to higher size-specific settling velocities, and generally higher carbon-to-volume ratios. Applying our scaling approach to a global data set of vertical aggregate abundance and size distribution, we found that small aggregates contribute 40-70% to total carbon fluxes in situ . Teaser Improved sinking velocity prediction for marine aggregates highlights the contribution of small aggregates to carbon sequestration.

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