催化作用
水煤气变换反应
化学
选择性
化学工程
氧化态
金属
碱金属
材料科学
理论(学习稳定性)
空间速度
组合化学
氧化还原
Atom(片上系统)
离子
对偶(语法数字)
无机化学
反应条件
多相催化
氧气
过渡金属
纳米技术
降级(电信)
单位(环理论)
氧原子
结晶学
作者
Xu Jing,Lingling Zhang,Meng Zhao,Lu Sun,Qing Xie,Ying Wang,Shuyan Song,Hongjie Zhang,Xiao Wang
标识
DOI:10.1002/anie.202519311
摘要
Abstract The reverse water gas shift (RWGS) reaction holds significant industrial importance. While directly incorporating alkali metals can enhance the catalytic activity, its contribution to enhancing stability remains rather limited. Encapsulating metal centers within zeolites offers a solution to increase stability, however the fine structure of inner active units is hard to control, bringing negative impact on activity. In this work, a dual ligand‐protected strategy to control the hybridization of Pt and Na species within silicalite‐1 (S1) frameworks is reported, which possesses simultaneously‐improved activity and stability compared with conventional RWGS catalysts. Specifically, the catalyst achieves an impressive turnover frequency (TOF) of 207,156.4 h −1 with 100% CO selectivity at 350 °C. Moreover, it retains high activity even after undergoing accelerated aging tests at 800 °C. Further mechanistic investigations uncover the formation of a novel Pt─O─Na─Si unit within the confined space of S1, where a skeletal oxygen atom simultaneously coordinates with one Na⁺ ion and one Pt atom. In this hybrid structure, the Pt centers exhibit a significantly‐raised oxidation state, which was identified as the key factor for the enhancement in RWGS activity: the positive oxidation state facilitates CO desorption, thereby promoting the forward progression of the reaction.
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