Flexible Z-scheme heterojunction membrane reactors for visible-light-driven antibiotic degradation and oil-water separation

In this study, to overcome the problems of photo corrosion and structural instability, an attempt was made to construct a semiconductor heterojunction with MOF that can resist photo corrosion and reduction to adjust the electron (e−) transport path. The crystal stability and photo corrosion resistance are improved by creating Z-type heterojunctions to change the electron transfer path of Ag photocatalysts. MOFs have unique optical, electrical, and catalytic properties and thus play a key role in optimizing electron transfer pathways. Even if a semiconductor-catalyst heterojunction is constructed, migration-matched catalysts induce a cascade of crystal reduction and photo corrosion in a built-in electric field. At this time, PENS provides an electron acceptor platform, which can temporarily store photoelectrons, prevent the decrease of photoelectrons to the crystal, and improve electron transfer efficiency. The degradation of antibiotics and dyes assessed the resulting impact on photocatalytic efficiency under simulated sunlight, and photocatalytic activity was measured with an eye toward real outdoor applications. Due to the synergistic effect of the double self-cleaning structure, the ultrafiltration membrane exhibits superhydrophilic/underwater superoleophobic properties. It shows excellent separation efficiency and recyclability in the separation of oil-in-water emulsion experiments.