Metal- and Site-Specific Roles of High-Entropy Spinel Oxides in Catalytic Oxidative Polymerization of Water Contaminants

催化作用 尖晶石 聚合 氧化磷酸化 化学 金属 污染 环境化学 化学工程 无机化学 材料科学 有机化学 冶金 生态学 生物化学 聚合物 工程类 生物
作者
Yalan Mo,Zhihao Tian,Kunsheng Hu,Wei Ren,Lu Xiao,Xiaoguang Duan,Shaobin Wang
出处
期刊:ACS Catalysis [American Chemical Society]
卷期号:15 (8): 5928-5942 被引量:41
标识
DOI:10.1021/acscatal.5c00854
摘要

High-entropy spinel oxides (HESOs) have emerged as promising catalysts due to their multimetal interactions, compositional flexibility, and superior structural stability; however, the roles of each metal in catalytic reactions remain elusive. In addition, catalytic organic recycling via polymerization has attracted increasing attention as a sustainable strategy for wastewater treatment. Herein, we synthesized HESOs incorporating five transition metals (Fe, Co, Ni, Cr, and Mn) using a low-temperature microwave-assisted method to achieve highly dispersed metal species in nanoparticles for catalytic peroxymonosulfate (PMS) activation for organic transformation and elucidate the different metal site catalysis. Comprehensive characterizations confirmed the single-phase spinel structure, high configurational entropy, and site-selective cation distribution among the tetrahedral and octahedral sites within the HESOs. The HESOs demonstrated superior activity in PMS activation for the polymerization of bisphenol A (BPA), outperforming single metal-based oxides. Mechanistic studies revealed that BPA degradation followed a nonradical electron transfer pathway mediated by surface catalyst-PMS* complexes. The enhanced catalytic activity was attributed to the distinct roles of individual metal components at different sites: Co served as the predominant electron donor, Cr facilitated strong PMS adsorption, and Ni supported the redox cycling of Co2+/Co3+. These metal-specific contributions synergistically enhanced the PMS activation efficiency, enabling BPA removal via oxidative polymerization with minimal oxidant consumption. Overall, this work provides in-depth insights into the metal- and site-specific roles in multisite synergy of HESOs and demonstrates their innovative application in Fenton-like catalysis toward fast water decontamination in a more selective and low-chemical-consumption manner for carbon recycling.
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