Effects of organic matter on the aggregation of anthropogenic microplastic particles in turbulent environments

Xiaoteng Shen, Hong Huo, Ying Zhang, Yuliang Zhu, Michael Fettweis, Qilong Bi, Byung Joon Lee, Jerome P.Y. Maa, Qiqing Chen

Research output: Contribution to journalArticlepeer-review

10 Scopus citations

Abstract

Biofilm-coated microplastics are omnipresent in aquatic environments, carrying different organic matter (OM) that in turn influences the flocculation and settling of microplastic aggregates. In this study, the effects of chitosan, guar gum, humic acid, and xanthan gum on the flocculation of anthropogenic microplastics are examined under controlled shear through the mixing chamber experiments. The results show that all of the selected OMs have positive effects on biofilm culturing and thus enhance the growth of microplastic flocs, with more evident promoting effects for cationic and neutral OMs (i.e., chitosan and guar gum) than anionic OMs (i.e., humic acid and xanthan). No critical shear rate is observed in the size vs. shear relationship based on our measurements. In addition, the quadrature-based two-class population balance model is employed to track the development of bimodal floc size distributions (FSDs) composed of small and large microplastic flocs. The model predictions show reasonable agreement with the observed FSDs. The largest error of settling flux from the two-class model is 7.8% in contrast with the reference value measured by the camera-based FSDs with 30 bins. This study highlights the role of different OMs on microplastic flocculation and indicates that a two-class model may be sufficient to describe microplastic transport processes in estuaries.

Original languageEnglish
Article number119706
JournalWater Research
Volume232
DOIs
StatePublished - 1 Apr 2023

Keywords

  • Biofilm
  • Microplastics
  • Mixing chamber
  • Organic matters
  • Population balance model

Fingerprint

Dive into the research topics of 'Effects of organic matter on the aggregation of anthropogenic microplastic particles in turbulent environments'. Together they form a unique fingerprint.

Cite this