Non-metallic Lewis acid sites enhance the activation of peracetic acid by cobalt-iron spinel for micropollutant decontamination: The critical role of Lewis acid sites as electron shuttles

Abstract

Spinel is a common activator for peroxides, e.g., peracetic acid (PAA), in wastewater treatment, but suffers from insufficient electron transfer capacity at the active site and thus the limited activation capacity. Lewis acids are recognized for their capacity to interact with electrons and activate active sites, playing a crucial role in enhancing oxidant adsorption, shortening catalytic reaction distances, and increasing reaction kinetics. Herein, tellurium (Te), a typical Lewis acid, was introduced into cobalt-iron spinel (TCF) as an electron shuttler to improve the electron transfer capacity and thus boost the PAA activation. Results show that the degradation rate of sulfamethoxazole (SMX) with PAA activated via TCF is 4.0 times higher compared with cobalt-iron spinel (CF). Electron spin resonance (ESR) analysis and quenching experiments indicated acetylperoxyl radicals (CH3C(O)OO·) as the dominant reactive species in SMX degradation. Electrochemical tests revealed that the introduction of Lewis acid improved the charge transfer ability and charge utilization efficiency of the catalysts, exhibiting less electronic resistance and superior redox properties. Density functional theory (DFT) calculation suggests that the introduction of Lewis acid optimizes the electron distribution of the catalyst, and reduces the crucial reaction energy barriers for PAA activation. Additionally, the distinctive structural environment of Lewis acid renders TCF to exhibit excellent stability and resistance to complicated matrices in PAA activation. This work provides valuable insights into the Lewis acid regulating bimetallic catalyst performance and understanding the intrinsic interaction mechanisms, thereby establishing a critical groundwork for addressing prevailing wastewater treatment.