Influence of synthetic wastewater on entrapped air on the isotactic and atactic polypropylene microplastic surfaces

The municipal wastewater collection system is recognized as an initial point of interaction between microplastics (MPs) and the urban wastewater matrix. The raw wastewater contains a wide variety of organic and inorganic substances including chemicals and heavy metals. However, the fate of MPs in ur...

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Bibliographic Details
Published in:Journal of environmental health science and engineering 2020-12, Vol.18 (2), p.1569-1579
Main Authors: Nikpay, Mitra, Eqtesadi, Siamak, Krebs, Peter
Format: Article
Language:English
Subjects:
Earth and Environmental Science
Environment
Environmental Economics
Environmental Engineering/Biotechnology
Environmental Health
Environmental Law/Policy/Ecojustice
Political aspects
Polypropylene
Quality of Life Research
Research Article
Sewer systems
Waste Management/Waste Technology
Wastewater
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Summary:The municipal wastewater collection system is recognized as an initial point of interaction between microplastics (MPs) and the urban wastewater matrix. The raw wastewater contains a wide variety of organic and inorganic substances including chemicals and heavy metals. However, the fate of MPs in urban sewer systems is not yet well understood. In this work two types of virgin polypropylene (PP) samples, isotactic (iPP) and atactic (aPP), were exposed to two synthetic wastewater solutions in order to study their effects on the physical properties of the hydrophobic polymer surfaces. Particular attention was paid to the pollution adhesion at the air-liquid-solid interfaces of the surface air pockets entrapped on the polymer surfaces. The first wastewater solution consists of mixed fat, oil and grease (FOG) - surfactant and another which is an exclusively contained wastewater surfactant. The interaction experiment over a period of 10 min between the polymer’s air pocket and solutions indicated that the size of the bubble in the mixed FOG-surfactant solution increased more pronouncedly for iPP (%152) in contrast to aPP (%31) and was also compared with the greater surface roughness of the polymers. The size variation of the spherical cap on the immersed polymer surfaces were measured between 17 µm and 85 µm using image processing techniques while the data was analyzed by the Young-Laplace equation. The corresponding technical surface roughness of the polymers, the surface tension of the liquids and their air/water contact angle on the flat polymer surfaces were also measured. The results of this study indicated that surface air pockets influence the adsorption capacity of MPs and thus their buoyancy and contamination potential.
ISSN:2052-336X
2052-336X
DOI:10.1007/s40201-020-00575-9