Important effects of polypropylene on migration of ciprofloxacin in groundwater

To investigate the effect of microplastics on the transport and retention of antibiotics in subsurface environment, polypropylene (PP) and ciprofloxacin (CIP) are selected as typical microplastic and antibiotic contaminant, respectively. The key factors and main control mechanisms are systematically investigated using a combination of adsorption experiments, column experiments and numerical model. The adsorption experiments indicate the largest adsorption capacity of CIP on PP is 1.03 mg & BULL;g � 1. Simultaneously, the results of column experiments and numerical model suggest that PP can significantly affect the migration behavior and retention of CIP in porous media. CIP mobility is positively correlated to flow velocity, initial concentration of CIP and ionic strength (Na+, Ca2+ and Ba2+). Moreover, compared to monovalent cation (Na+), divalent cations (Ca2+, Ba2+) have a stronger enhancement effect on CIP mobility and a stronger inhibition effect on CIP retention in saturated porous media. The transport of CIP in saturated porous media containing PP is simulated by a single-point kinetic model, and the equations of the transport kinetic parameters of CIP are obtained through regression analysis. The research could help to gain insight into understanding the environmental behavior of antibiotic in the groundwater system, and provide scientific basis for the accurate prediction and assessment of environmental risk caused by microplastic and antibiotic in the groundwater system.

Automated summary

By conducting adsorption experiments, column experiments, and numerical modeling, this study systematically investigates the impact of microplastics on the transport and retention of antibiotics in subsurface environments. The results show that polypropylene (PP) has a significant influence on the migration behavior and retention of ciprofloxacin (CIP) in porous media. The findings also suggest that flow velocity, initial concentration of CIP, and ionic strength play important roles in CIP mobility, with divalent cations having a stronger effect than monovalent cations. This research provides insights into the environmental behavior of antibiotics in groundwater systems and contributes to the accurate prediction and assessment of environmental risks caused by microplastics and antibiotics.