The molecular interactions of organic compounds with tire crumb materials differ substantially from those with other microplastics

Tire materials are the most commonly found elastomers in the environment and they account for a significant fraction of microplastic pollution. In the discussions on the environmental impact of microplastics tire materials and their sorption properties have been largely overlooked. In this study we...

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Bibliographic Details
Published in:Environmental science--processes & impacts 2020-01, Vol.22 (1), p.121-13
Main Authors: Hüffer, Thorsten, Wehrhahn, Maren, Hofmann, Thilo
Format: Article
Language:English
Subjects:
Adsorption
Black carbon
Butadiene
Carbon black
Elastomers
Environmental impact
Hexadecane
Hydrophobicity
Microplastics
Microplastics - chemistry
Molecular interactions
Organic Chemicals - chemistry
Organic compounds
Plastic pollution
Rubber
Soot
Sorbates
Sorption
Styrene
Styrenes
Water pollution
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Summary:Tire materials are the most commonly found elastomers in the environment and they account for a significant fraction of microplastic pollution. In the discussions on the environmental impact of microplastics tire materials and their sorption properties have been largely overlooked. In this study we used experimental sorption data from six organic probe sorbates sorbing to two tire materials and their major components, styrene butadiene rubber and carbon black, to gain a better understanding of the underlying sorption processes of tire materials. Commonly applied models used to describe non-linear sorption processes were unable to fully explain sorption to tire materials but showed that absorption into the rubber fraction dominated the sorption process. Hydrophobicity was approximated using the hexadecane-water partitioning constant, which correlated very well with the distribution data obtained for styrene rubber, whereas the correlations between hydrophobicity of sorbates and the sorption data to the tire materials were poor. Although hydrophobicity plays an important role in sorption to tire materials, additional interactions must be taken into account. Overall, the processes involved in sorption to tire materials differed significantly from those governing sorption to other microplastics. Sorption of organic compounds to tire crumb materials highly resembles sorption to the rubber fraction and less sorption to carbon black and sorption to tire materials differs substantially from sorption to other microplastics.
ISSN:2050-7887
2050-7895
DOI:10.1039/c9em00423h