Abstract
Microplastics represent a significant environmental threat owing to their persistence and resistance to degradation. Their co-occurrence with heavy metals in aquatic environments exacerbates the risks of complex pollution. While most current research focuses on conventional microplastics such as polyethylene and poly-(vinyl chloride), functionalized microplastics, which exhibit richer functional groups and more complex environmental behaviors, remain insufficiently studied. This research examines the adsorption behaviors of cadmium (Cd(2) (+)), copper (Cu(2) (+)), and lead (Pb(2) (+)) onto three types of functionalized microplastics: polyacrylate (PAT), biobased polyurethane (BPU), and petroleum-based polyurethane (PPU). Analyses based on Langmuir and Freundlich isotherm models indicate that microplastics with a particle size of 150 μm exhibit significantly enhanced adsorption capacities for Cd(2) (+), Cu(2) (+), and Pb(2) (+), showing increases of 5-18.62, 12.91-18.04, and 8.7-12.31%, respectively, compared to larger particles (1-2 mm). Among the tested materials, polyacrylate (PAT) exhibited the strongest adsorption affinity, with Langmuir maximum capacities (q (m)) of 34.68, 29.85, and 12.31 mg/g for Pb(2) (+), Cu(2) (+), and Cd(2) (+), respectively, following the order: Pb(2) (+) > Cu(2) (+) > Cd(2) (+). Furthermore, UV aging increased the adsorption capacity of PAT for Cd(2) (+) from 7.07 to 11.22 mg/g, as described by the pseudo-second-order model. However, the rate constant (k (2)) decreased from 0.027 to 0.006 g/(mg·min), indicating slower adsorption kinetics. These findings provide valuable insight into the interaction mechanisms between microplastics and heavy metals, offering a scientific basis for assessing their copollution behavior and ecological risks.