Tailoring the Electronic Metal–Support Interactions in Supported Atomically Dispersed Gold Catalysts for Efficient Fenton‐like Reaction

The atomically dispersed metal is expected as one of the most promising Fenton‐like catalysts for the degradation of recalcitrant organic pollutants (ROPs) by the strong “electronic metal–support interactions” (EMSIs). Here, we develop an atomically dispersed metal–atom alloy made by guest Au atoms substitute host V atoms in the two‐dimensional VO2(B) nanobelt support (Au/VO2) to activate Fenton‐like oxidation for elimination of ROPs. The 2D nanobelt structure enlarges the exposure of atomically Au thus increasing the number of active sites to absorb more S2O82− ions. And the EMSIs regulate the charge density in Au atoms to present positive charge Au+, lowering the energy barrier of S2O82− decomposition to produce SO4.−. The Au/VO2 catalyst possesses excellent durable and reliable characteristics and exhibits record‐breaking efficiency with TOF as high as 21.42 min−1, 16.19 min−1, and 80.89 min−1 for rhodamine, phenol, and bisphenol A degradation, respectively. A substituted solid solution was used to achieve self‐exfoliation of synthetic materials and optimize electronic metal–carrier interactions to increase the material's high efficiency and stable water treatment catalytic performance.