Efficient Exciton Dissociation on Ceria Chelated Cerium‐Based MOF Isogenous S‐Scheme Photocatalyst for Acetaldehyde Purification

Long‐term exposure to low concentration indoor VOCs of acetaldehyde (CH3CHO) is harmful to human health. Thus, a novel isogenous heterojunction CeO2/Ce‐MOF photocatalyst is synthesized via a one‐step hydrothermal method for the effective elimination of CH3CHO in this work. This CeO2/Ce‐MOF photocatalyst performs well in CH3CHO removal and achieves an apparent quantum efficiency of 7.15% at 420 nm, which presents ≈6.7 and 3.4 times superior to those generated by CeO2 and Ce‐MOF, respectively. The enhanced efficiency is due to two main aspects including i) an effective photocarrier separation ability and the prolonged reaction lifetime of excitons play crucial roles and ii) the formation of an internal electric field (IEF) is sufficient to overcome the considerable exciton binding energy, and increases the exciton dissociation efficiency by up to 50.4%. Moreover, the reasonable pathways and mechanisms of CH3CHO degradation are determined by in situ DRIFTS analysis and simulated DFT calculations. Those results demonstrated that S‐scheme heterojunction successfully increases the efficiency of harmful volatile organic compounds elimination, and it offers essential guidance for designing rare earth‐based MOF photocatalysts. Long‐term exposure to low‐concentration acetaldehyde VOCs indoors is harmful to human health. This study fabricates a novel isogenous CeO2/Ce‐MOF S‐scheme heterojunction photocatalyst and effective photocarrier exciton dissociation ability and prolonged excitons lifetime on it play crucial roles of to realize high efficiency purification of persistent indoor contaminant.