Microplastics separation and subsequent carbonization: Synthesis, characterization, and catalytic performance of iron/carbon nanocomposite

Microplastics (MPs), as emerging contaminants, have gained increasing global attention due to their wide distribution and serious threats. Physical techniques are effective for separating MPs from water environment such as in wastewater treatment plants, but the disposal of the separated MPs becomes an emerging problem. A novel strategy of MPs separation and subsequent sustainable disposal is proposed. MPs separation was effectively obtained via iron coagulation. Conversion of the coagulated material into carbon material was conducted by facile carbonization. The formation of magnetic carbon/iron nanocomposite was verified by various characterization methods. Carbon/iron nanocomposite obtained at 800 degrees C (MPC800) was used as heterogeneous catalyst for evaluating the degradation of a toxic Rhodamine B (RhB). The effects of H2O2, pH, and temperature on degradation performance were studied associated with RhB removal efficiency and kinetic analysis. Under proper conditions, RhB removal of 97.57% was obtained at 20 min. The activation energy of RhB degradation is 46 kJ/mol, lower than that of previous reports. Quenching tests and electron spin resonance spectra verified the dominant role of center dot OH radical in RhB degradation. Conversion of MPs into effective catalyst for wastewater treatment offers a sustainable strategy for MPs disposal, guided by the waste treating waste concept.

Automated summary

The study proposed a novel strategy for separating microplastics using iron coagulation and carbonization, and conversion of separated microplastics into carbon/iron nanocomposites for degrading toxic dyes in wastewater, offering a sustainable method for microplastic disposal.