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Modeling the transport and residence time of microplastic particles in lakes and reservoirs

2024 Score: 45 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Jan H. Fleckenstein, Benjamin Gilfedder Lisa Jagau, Lisa Jagau, Lisa Jagau, Vadym Aizinger, Lisa Jagau, Lisa Jagau, Lisa Jagau, Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Lisa Jagau, Lisa Jagau, Jan H. Fleckenstein, Jan H. Fleckenstein, Lisa Jagau, Jan H. Fleckenstein, Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Jan H. Fleckenstein, Lisa Jagau, Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Jan H. Fleckenstein, Lisa Jagau, Benjamin Gilfedder Lisa Jagau, Jan H. Fleckenstein, Jan H. Fleckenstein, Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Vadym Aizinger, Vadym Aizinger, Vadym Aizinger, Benjamin Gilfedder Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Benjamin Gilfedder Vadym Aizinger, Benjamin Gilfedder Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Jan H. Fleckenstein, Jan H. Fleckenstein, Benjamin Gilfedder Jan H. Fleckenstein, Benjamin Gilfedder Benjamin Gilfedder Jan H. Fleckenstein, Jan H. Fleckenstein, Benjamin Gilfedder

Summary

This study developed and validated a model for simulating the transport and residence time of microplastic particles in lakes and reservoirs, showing that hydrodynamic factors, particle density, and lake morphology together determine where microplastics accumulate.

Microplastic (MP) particles are assumed to be potentially harmful to organisms in the hydrosphere. To better assess the exposure and the associated risk it is essential to quantify the transport and sedimentation behavior of MP particles in aquatic environments.Using the Delft3D Flexible Mesh Suite we set up a three-dimensional hydrodynamic and MP transport model for lakes and reservoirs. Our focus is on modeling polymers with different densities and particle sizes to identify patterns of particle residence time and sedimentation. The reservoir Gro&#223;er Brombachsee in Germany serves as the research site with realistic forcings and boundary conditions.We present first results for horizontal and vertical distribution patterns for different polymer types. We found that the distribution of MP in the computational domain is strongly affected by both particle density and particle size. Smaller, lighter particles are spread over the entire horizontal extent of the reservoir, but particles of higher density or of larger size settle within a limited area around the inflow location, indicating a much higher settling velocity.

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