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Modeling Microplastic Transport in Watershed and Estuarine Systems: A Coupled DHSVM-FVCOM Approach
Summary
Scientists built a coupled computer model linking a watershed hydrology model to an ocean circulation model to simulate how microplastics move from land through rivers into estuarine and coastal waters. Applied to the Delaware River Estuary, the framework can help predict where microplastics accumulate, which is essential for designing targeted monitoring and cleanup interventions.
Abstract Microplastics (MPs) are an emerging environmental concern owing to their widespread presence and ecological impacts. We develop a coupled watershed–estuary modeling framework to simulate MP transport from terrestrial sources to estuarine systems. The Distributed Hydrology Soil Vegetation Model (DHSVM) is enhanced to represent point and nonpoint MP sources and is coupled with the Finite Volume Community Ocean Model (FVCOM) to capture estuarine transport. Applied to the Delaware River Basin, the framework simulates MP buildup and wash-off, including airborne deposition and wastewater treatment plant (WWTP) discharges. Coupling the estuary model substantially alters MP discharge to the ocean, highlighting retention within Delaware Bay from salinity-induced circulation. MP retention on land is strongly influenced by watershed topography, urban distribution, and source configuration, with the “Lower Delaware” subwatershed exhibiting minimal residence time. These results demonstrate the importance of watershed–estuary coupling for accurate MP export estimates and provide a framework for evaluating MP fate in aquatic environments.
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