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Autori principali: Witzmann, Thomas, Ramsperger, Anja F. R. M., Liu, Hao, Lu, Yifan, Schmalz, Holger, Kurzweg, Lucas, Börner, Tom C. D., Harre, Kathrin, Greiner, Andreas, Laforsch, Christian, Kress, Holger, Bogner, Christina, Gekle, Stephan, Fery, Andreas, Auernhammer, Günter K.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2509.14371
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author Witzmann, Thomas
Ramsperger, Anja F. R. M.
Liu, Hao
Lu, Yifan
Schmalz, Holger
Kurzweg, Lucas
Börner, Tom C. D.
Harre, Kathrin
Greiner, Andreas
Laforsch, Christian
Kress, Holger
Bogner, Christina
Gekle, Stephan
Fery, Andreas
Auernhammer, Günter K.
author_facet Witzmann, Thomas
Ramsperger, Anja F. R. M.
Liu, Hao
Lu, Yifan
Schmalz, Holger
Kurzweg, Lucas
Börner, Tom C. D.
Harre, Kathrin
Greiner, Andreas
Laforsch, Christian
Kress, Holger
Bogner, Christina
Gekle, Stephan
Fery, Andreas
Auernhammer, Günter K.
contents Microplastics (MPs), though less dense than water, are frequently recovered from sediments in aqueous environments, indicating they can cross the buoyancy barrier. We quantify eco-corona mediated MP-sediment attraction and MP transport from the nanoscale to the macroscale, linking all scales to a coherent mechanism explaining how MP overcome buoyancy and settle in sediments through interaction with suspended sediment. Colloidal probe atomic force microscopy (CP-AFM) detected attractive forces (0.15 - 17 mN/m) enabling heteroaggregation. Microscale tests confirmed aggregation and on larger scales sediment retention more than doubled with an eco-corona. Simulations showed that environmental shear force ($4 \cdot 10^{-4} mN/m$) cannot disrupt aggregates. In sedimentation columns, biofilm-covered MPs settled twice as often as plain MPs in bentonite suspensions. MP retention increased by 32 %. These results demonstrate that eco-corona/biofilm-mediated heteroaggregation is a robust pathway for MP sinking, accumulation, and retention in sediment beds. By identifying physical interaction thresholds and aggregation stability, we provide mechanistic insight into MP fate, highlight probable accumulation hotspots, and offer an evidence base for improved risk assessment and environmental modelling.
format Preprint
id arxiv_https___arxiv_org_abs_2509_14371
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle How Microplastics cross the Buoyancy Barrier: A multi-scale Study
Witzmann, Thomas
Ramsperger, Anja F. R. M.
Liu, Hao
Lu, Yifan
Schmalz, Holger
Kurzweg, Lucas
Börner, Tom C. D.
Harre, Kathrin
Greiner, Andreas
Laforsch, Christian
Kress, Holger
Bogner, Christina
Gekle, Stephan
Fery, Andreas
Auernhammer, Günter K.
Soft Condensed Matter
Microplastics (MPs), though less dense than water, are frequently recovered from sediments in aqueous environments, indicating they can cross the buoyancy barrier. We quantify eco-corona mediated MP-sediment attraction and MP transport from the nanoscale to the macroscale, linking all scales to a coherent mechanism explaining how MP overcome buoyancy and settle in sediments through interaction with suspended sediment. Colloidal probe atomic force microscopy (CP-AFM) detected attractive forces (0.15 - 17 mN/m) enabling heteroaggregation. Microscale tests confirmed aggregation and on larger scales sediment retention more than doubled with an eco-corona. Simulations showed that environmental shear force ($4 \cdot 10^{-4} mN/m$) cannot disrupt aggregates. In sedimentation columns, biofilm-covered MPs settled twice as often as plain MPs in bentonite suspensions. MP retention increased by 32 %. These results demonstrate that eco-corona/biofilm-mediated heteroaggregation is a robust pathway for MP sinking, accumulation, and retention in sediment beds. By identifying physical interaction thresholds and aggregation stability, we provide mechanistic insight into MP fate, highlight probable accumulation hotspots, and offer an evidence base for improved risk assessment and environmental modelling.
title How Microplastics cross the Buoyancy Barrier: A multi-scale Study
topic Soft Condensed Matter
url https://arxiv.org/abs/2509.14371