Nano-island-encapsulated cobalt single-atom catalysts for breaking activity-stability trade-off in Fenton-like reactions
Zhiquan Zhang, Pijun Duan, Jiexuan Zheng, Yun-Qiu Xie, Chang‐Wei Bai, Yi-Jiao Sun, Xin‐Jia Chen, Fei Chen, Han‐Qing Yu
Abstract
Single-atom catalysts (SACs) have been increasingly acknowledged for their performance in sustainable Fenton-like catalysis. However, SACs face a trade-off between activity and stability in peroxymonosulfate (PMS)-based systems. Herein, we design a nano-island encapsulated single cobalt atom (CoSA/Zn.O-ZnO) catalyst to enhance the activity and stability of PMS activation for contaminant degradation via an “island-sea” synergistic effect. In this configuration, small carrier-based ZnO nanoparticles (the “islands”) are utilized to confine and stabilize Co single atoms. The expansive ZnO substrate (the “sea”) upholds a neutral microenvironment within the reaction system. The CoSA/Zn.O-ZnO/PMS system exhibits a remarkable selectivity in exclusively generating sulfate radicals (SO4•-), leading to a complete removal of various recalcitrant pollutants within a shorter period. Characterized by minimal leaching of active sites, robust catalytic performance, and low-toxicity decontamination, this system proves highly efficient in multiple treatment cycles and complex water matrices. The design effectively breaks the activity-stability trade-off typically associated with SACs. SACs are known for their Fenton-like catalytic performance but face a trade-off between activity and stability in PMS -based systems. Here, authors address this issue by developing a nano-island encapsulated Co SAC that enhances the activity and stability of PMS activation via an “island-sea” effect.