Application of novel dual-ligand co metal-organic framework/graphene oxide for electrocatalytic oxidative degradation of bisphenol A in marine wastewater

Abstract

The adjustment of the electron distribution of 2D metal-organic frameworks (2D-MOFs), as a hot anode candidate for electrocatalytic oxidation, is crucial for its application. In this work, a new electron distribution was achieved with dual-ligand connection and graphene oxide (GO) loading and the complex of dual-ligand 2D-MOF/GO (Co-IH/GO) exhibit faster electron transfer efficiency (Rct = 62.5) and more active sites (I_D/I_G = 1.01). Co-IH/GO demonstrated excellent electrocatalytic performance and achieved 100 % electrocatalytic degradation of bisphenol A (BPA) within 10 min. In addition, superior properties of stability, temperature tolerance, and pH tolerance were achieved, after 5 cycles of degradation, the catalyst was able to maintain 100 % degradation efficiency, Capable of maintaining good degradation performance over a temperature range of 25 °C–45 °C and a wide pH range of pH = 5–11. Both experimental and electron paramagnetic resonance analysis results indicated that ¹O₂ acted as the dominant active substrate. With the involvement of Cl⁻ in marine wastewater, activated chlorine was also generated during the reaction, which contributed to fast BPA degradation. Furthermore, the established dual-ligand 2D-MOF/GO electrocatalytic system exhibited superior activity for the degradation of dyes and complex microflora, while the solar-driven degradation experiment shed light on the independence of fossil and stationary sources of energy.