催化作用
材料科学
反应性(心理学)
过渡金属
氧化物
贵金属
氧化还原
化学工程
工作(物理)
反应机理
纳米颗粒
一氧化碳
金属
纳米技术
铂金
机制(生物学)
无机化学
科技与社会
催化氧化
降级(电信)
光化学
耐久性
燃料电池
多相催化
作者
Tiantian Zhang,Yan Wang,Liu Yang,Kaili Xu,Zhiyong Ding,Hao Qu,Na Young Kang,Xinya Wu,Cheng Zhang,Mi Yan,Pengfei Xie
摘要
ABSTRACT The diesel oxidation catalysts (DOC) have been challenged by the high cost of noble metal and limited reactivity at low temperature. Herein, we report PtSmMnCoNb high‐entropy oxide nanoparticles supported single‐atom Pt catalyst, which achieves 90% conversion for CO at 100°C, for C 3 H 6 at 208°C, and 50% conversion for NO x at 203°C. This catalyst also achieves a thermodynamically stabilized configuration, which exhibits a long‐term durability benefited from high‐entropy effects. A combined experimental and theoretical analysis reveals the electron‐rich character of Pt δ+ sites derived by the strong interaction involved in abundant Pt‐O‐Metal interfaces, which accounts for the effective activation for reactants, leading to a transition in the reaction mechanism from Mars‐van Krevelen to Eley‐Rideal. This work provides a design paradigm of advanced catalysts for the integrated removal of multi‐pollutants.
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