Fabrication of [email protected](Fe) for enhanced visible-light photocatalysis degradation of organophosphorus contaminant

Metal-organic frameworks (MOFs) have become one of the most attractive classes of materials due to their versatile features. It is desirable to evaluate the photocatalysis performance of MOFs in aquatic medium. In this study, graphene oxide compositing MIL-101(Fe) ([email protected](Fe)) was fabricated. Based on this MOF, a light/MOF/H2O2 photocatalysis system was developed to degrade tris(2-chloroethyl) phosphate (TCEP). [email protected](Fe) has a lower band gap energy (2.17 eV) than MIL-101(Fe) (2.41 eV), suggesting an expansion of visible light absorption from 520 nm to 570 nm. Under 420 nm irradiation, removal of TCEP under the 15%[email protected](Fe) photocatalysis system followed pseudo-first-order kinetic with a reaction rate constant at 1.64 × 10−3 s-1. Using [email protected](Fe), a fast activation and electron transfer was achieved due to the high conductibility of GO, resulting in a higher removal efficiency of TCEP (∼95% at 30 min) than using MIL-101(Fe) (∼50%). The basic reaction mechanism involved the excitation of electrons from HOMO (oxygen orbitals in ligands) to LUMO (Fe(II)/Fe(III) in core nodes) induced by visible light irradiation, followed by the electron transport between [email protected](Fe) and H2O2 to generate OH. [email protected](Fe) visible-light photocatalysis would be a potential treatment process for organic contaminants.