Fe3C/Fe nanoparticles decorated three-dimensional nitrogen-doped carbon foams for highly efficient bisphenol A removal through peroxymonosulfate activation

The design of heterogeneous catalysts has become one of the most important steps in the popularization of advanced oxidation processes for wastewater remediation. With a nitrate-assisted polymer-bubbling strategy, we prepared three-dimensional carbon foams decorated by commensal Fe3C/Fe nanoparticles through a direct pyrolysis of the mixture of polyvinyl pyrrolidone and ferric nitrate nonahydrate. The as-obtained composites, Fe3C/ Fe@NCFs, are employed as heterogeneous peroxymonosulfate (PMS) activators to remove bisphenol A (BPA) in aquatic environments with a predetermined concentration. It is found that both Fe3C/Fe nanoparticles and N doped carbon frameworks can activate PMS to release powerful oxidative species for BPA removal. The effect of pyrolysis temperature on the catalytic performance of Fe3C/Fe@NCFs is studied in detail. The results reveal that high pyrolysis temperature induces the agglomeration of Fe3C/Fe nanoparticles and the loss of N content, and low pyrolysis temperature only generates low-crystallinity carbon frameworks and small proportion of graphitic N configuration. Therefore, Fe3C/Fe@NCFs from moderate temperature (700 degrees C) can produce the highest BPA removal efficiency. The synergy of Fe3C/Fe nanoparticles and N-doped carbon frameworks, as well as the structure advantages is clearly established in comparison with some control samples. Quenching experiments and electron paramagnetic resonance (EPR) tests indicate that BPA can be degraded in both radical pathway and non radical pathway, where SO4 center dot-, center dot O-2(-) , and O-1(2) are primary reactive species. In addition, the influences of some routine factors and actual water backgrounds were also investigated and analyzed comprehensively.

Automated summary

The design of heterogeneous catalysts is crucial for advanced oxidation processes in wastewater treatment. Fe3C/Fe nanoparticles and N-doped carbon frameworks are found to activate PMS for efficient removal of BPA. The catalytic performance of Fe3C/Fe@NCFs is influenced by the pyrolysis temperature, with moderate temperature (700 degrees C) producing the highest BPA removal efficiency.