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Experimental data to calibrate the plastic dispersal model: effect of biofouling on vertical flux for different polymer types. PLUXIN Deliverable D2.3
Asselman, J.; Janssen, C.; Vercauteren, M. (2022). Experimental data to calibrate the plastic dispersal model: effect of biofouling on vertical flux for different polymer types. PLUXIN Deliverable D2.3. Ghent University: Ghent . 48 pp. https://dx.doi.org/10.48470/73

Project Top | Authors 
  • Plastic Flux for Innovation and Business Opportunities in Flanders

Authors  Top 
  • Asselman, J.
  • Janssen, C.
  • Vercauteren, M.

Abstract
    Today, we are surrounded by a plethora of plastic objects, ranging from everyday items to complex products and machines. During production, use and waste management, emission of plastics of all sizes (micro – macro) to various environmental compartments occur.
    The PLUXIN project aims to close the knowledge gap on the plastic flux by use of numerical modelling to gain insight into the fate and transport of plastic debris across environmental compartments. Understanding the sinking behaviour of microplastics in freshwater is essential for assessing their environmental impact, guiding research efforts, and formulating effective policies to mitigate plastic pollution. Sinking behaviour is a complex process driven by plastic density, environmental factors and particle characteristics. Moreover, the growth of biological entities on the plastic surface can affect the total density of the microplastics and thus influence the sinking behaviour. Yet, our understanding of these processes in freshwater is still limited. Our research thus focused on studying biofilm growth on microplastics in freshwater. Therefore, we evaluated biofilm growth on five different polymer types (both microplastic particles and plates) which were incubated in freshwater for 63 days in a controlled laboratory setting. Biofilm growth (mass-based) was used to compare biofilm growth between polymer types, surface roughness and study the changes over time. Understanding the temporal aspect of biofilm growth enabled us to refine calculations on the predicted effect of biofilm growth on the settling behaviour in freshwater. The results showed that biofilm formation is polymer-specific but also affected by surface roughness, with a rougher surface promoting biofilm growth. For PET and PS, biofilm tended to grow exponentially during 63 days of incubation. Based on our calculations, biofilm growth did affect the sinking behaviour differently based on the polymer type, size and density. Rivers can function as sinks for some particles such as large PET particles. Nevertheless, for others, the likelihood of settling within river systems appears limited, thereby increasing the probability of their transit to estuarine or oceanic environments under hydrometeorological influences. While the complexity of biofilm dynamics on plastic surfaces is not fully understood, our findings help to elucidate the effect of biofilms on the vertical behaviour of microplastics in freshwater systems hereby offering knowledge to interpret observed patterns in environmental plastic concentrations.

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