Cr2O3 clusters on ZnO as hydrogen pools for efficient syngas‐to‐light olefins

IF 3.8 3区化学 Q2 CHEMISTRY, PHYSICAL

ChemCatChem Pub Date : 2024-08-27 DOI:10.1002/cctc.202401421

Beikai Ding, Chengsheng Yang, Yue Chen, Wei-Peng Shao, Fan Yang, Chi Zhang, Zheng Wang, Yongmei Liu, Yong Cao, Yifeng Zhu, Xinhe Bao

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Abstract

Interfaces of mixed oxide are often considered the primary catalytic sites, yet the functionalities of the surrounding environments are less understood. Composite oxides, particularly ZnO‐Cr2O3, show high activity and selectivity for syngas conversion, with ZnO dissociating H2 to hydrides and Cr2O3 activating CO. However, hydrides on ZnO cannot remain stable at temperatures above room temperature. Focusing on the puzzlingly high performance despite ZnO’s inability to stabilize active hydrides at reaction temperatures (300‐400 oC), we clarified the roles of each phase using models of Cr2O3/ZnO and ZnO/Cr2O3. Cr2O3 clusters on ZnO effectively stabilize and store hydrides, significantly enhancing syngas conversion compared to individual oxides or ZnO/Cr2O3. An acetate/ketene pathway on Cr2O3/ZnO was identified, driven by the unique role of Cr2O3 clusters in regulating local hydride and CO coverages, unlike other routes observed on ZnO/Cr2O3. These insights advance the understanding of the active structures and functionalities of mixed oxides in catalysis.

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氧化锌上的 Cr2O3 团簇是高效合成气制轻烯烃的氢池

混合氧化物的界面通常被认为是主要的催化场所，但人们对周围环境的功能性了解较少。复合氧化物，尤其是氧化锌-氧化铬，在合成气转化方面表现出很高的活性和选择性，氧化锌可将 H2 分解为氢化物，氧化铬可激活 CO。然而，氧化锌上的氢化物在室温以上无法保持稳定。尽管氧化锌无法在反应温度（300-400 oC）下稳定活性氢化物，但其性能却很高，针对这一令人费解的现象，我们使用 Cr2O3/ZnO 和 ZnO/Cr2O3 模型阐明了每种相的作用。与单个氧化物或 ZnO/Cr2O3 相比，ZnO 上的 Cr2O3 簇有效地稳定和储存了氢化物，显著提高了合成气转化率。与在 ZnO/Cr2O3 上观察到的其他途径不同，Cr2O3 团簇在调节局部氢化物和一氧化碳覆盖率方面发挥了独特的作用，从而确定了 Cr2O3/ZnO 上的乙酸酯/酮途径。这些见解加深了人们对混合氧化物在催化过程中的活性结构和功能的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ChemCatChem 化学-物理化学

CiteScore

8.10

自引率

4.40%

发文量

511

审稿时长

1.3 months

期刊介绍： With an impact factor of 4.495 (2018), ChemCatChem is one of the premier journals in the field of catalysis. The journal provides primary research papers and critical secondary information on heterogeneous, homogeneous and bio- and nanocatalysis. The journal is well placed to strengthen cross-communication within between these communities. Its authors and readers come from academia, the chemical industry, and government laboratories across the world. It is published on behalf of Chemistry Europe, an association of 16 European chemical societies, and is supported by the German Catalysis Society.