Effect of nanobubbles on the mobilization of microplastics in shorelines subject to seawater infiltration

• Published in: Environmental pollution (1987) Vol. 349; p. 123950
• Main Authors: Wang, Zheng, Lee, Kenneth, Feng, Qi, An, Chunjiang, Chen, Zhikun
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 15.05.2024
• Subjects: Column experiments; energy; Environmental Monitoring; glass; human health; hydrodynamics; hydrophilicity; Microplastics; Mobilization; Nanobubbles; pollution; Salinity; seawater; Seawater - chemistry; Tidal zone; tides; transient flow; Water Movements; Water Pollutants, Chemical; Mobilization; Nanobubbles; Microplastics; Column experiments; Tidal zone
• ISSN: 0269-7491; 1873-6424; 1873-6424
• DOI: 10.1016/j.envpol.2024.123950

The widespread presence of microplastics (MPs) in the ocean has varying degrees of impact on ecosystems and even human health. Coastal tidal zones are crucial in controlling the movement of MPs, which are influenced by waves and tidal forces. Meanwhile, natural nanobubbles (NBs) in the ocean can affect the hydrodynamic properties of the tidal zone. The mobilization of MPs in coastal tidal zones under the effect of NBs has been less studied. In this study, we explored natural NBs' influence on the mobilization of MPs in shorelines subject to seawater infiltration. Using glass beads as a substrate, a coastal porous environment was constructed through column experiments, and the pump-controlled water flow was used to study the transport of MPs subject to seawater movement within the substrate. The infiltration of MPs under continuous and transient conditions, as well as the upward transport induced by flood tide, were considered. The role of salinity in the interactions between NBs, MPs, and substrates was evaluated. Salinity altered the energy barriers between particles, which in turn affected the movement of MPs within the substrate. In addition, hydrophilic MPs were more likely to infiltrate within the substrate and had different movement patterns under continuous and transient flow conditions. The motion of the MPs within the substrate varied with flow rate, and NBs limited the vertical movement of MPs in the tidal zone. It was also observed that NBs adsorbed readily onto substrates, altering the surface properties of substrates, particularly their ability to attach and detach from other substances. [Display omitted] •The motion of the microplastics within the substrate varied with the flow pattern.•Nanobubbles limited the infiltration of microplastics in the tidal zone.•Salinity changed the interaction energy between particles and promoted aggregation.•Hydrophilicity affected the mobilization of microplastics in the substrate.•Nanobubbles attached to the substrates, thus changing their surface properties.