Synthesis of a Cu-Al bimetallic oxide @ PVDF composite membrane for the degradation of bisphenol a via peroxydisulfate activation: Performance and mechanism

Abstract

The presence of environmental endocrine-disrupting compounds, such as bisphenol A (BPA), in aquatic environments poses a significant risk to both ecological integrity and human health. Although CuO has been reported as a catalyst for activating peroxydisulfate (PDS) to degrade BPA, it exhibits certain limitations, including low catalytic efficiency, aggregation, and challenges in terms of separation and reusability. In this study, we developed a composite poly (vinylidene fluoride) (PVDF)-based membrane incorporating Cu-Al bimetallic oxide (Cu-Al) to address these issues. Results revealed that when employing the 7 wt% Cu-Al @ PVDF composite membrane to activate 1 mM PDS, approximately 95.3 % of BPA was degraded within 60 min in static experiments. Furthermore, this composite membrane exhibited remarkable efficacy across a broad pH range (3–11) and demonstrated excellent resistance against diverse anionic species. The removal process is proposed to be dominated by electron transfer between the composite membrane, PDS, and BPA via a two-step mechanism: Firstly, electron-rich Cu sites and oxygen vacancies were formed in the composite membrane, facilitating PDS adsorption and electron transfer from Cu sites to PDS to form a ligand complex; subsequently, BPA was adsorbed by the membrane and acted as an electron donor to be oxidized by the ligand complex. As a result, this system showed remarkable selectivity for degrading electron-rich organic compounds with ionization potentials below 9.0 eV. Overall, this work successfully fabricated a catalytic membrane exhibiting efficient PDS activation capability along with selective oxidation performance and facile reusability, making it highly promising for wastewater treatment.