Fe3O4 loaded on ball milling biochar enhanced bisphenol a removal by activating persulfate: Performance and activating mechanism

Abstract

In this study, pristine biochar (BC), ball milling biochar (MBC), Fe₃O₄ modified BC (Fe₃O₄@BC), and Fe₃O₄ modified MBC (Fe₃O₄@MBC) were prepared to compare the Bisphenol A (BPA) removal efficiency by activating persulfate (PDS). All catalysts exhibited excellent degradation rather than adsorption in the PDS system, and Fe₃O₄@MBC800 had the best BPA removal efficiency, with 96.73% degradation and negligible 1.43% adsorption due to the synergistic effect between MBC800 and Fe₃O₄ particles. Radical quenching experiments and electron paramagnetic resonance analysis indicated radical pathways, namely, SO₄∙^- and ∙OH, O₂∙^-, and non-radical pathway (¹O₂) involving BPA degradation. The abundant oxygen-containing groups, increased graphitization and mesopores of MBC800, and Fe³⁺/Fe²⁺ conversion of Fe₃O₄ particles facilitated PDS activation to produce reactive oxygen species. In addition, the superior electrochemical performance accelerated the electron transfer between the catalyst and PDS, promoting BPA degradation in the Fe₃O₄@MBC800/PDS system. More importantly, Fe₃O₄@MBC800 is resistant to environmental interference, including pH, anions, cations, and humic acid, and has good catalytic reusability and stability, which fulfills the requirements of engineering applications. Therefore, Fe₃O₄ loaded on ball-milled biochar provides a convenient strategy for preparing environmentally friendly, economical, and efficient carbon-based catalysts to remove organic contaminants.

Keywords: Ball milling biochar; Catalytic degradation; Fe(3)O(4) particles; Persulfate; Reactive oxygen species.