使用 Cu/ZnO 催化剂从 CO2 热合成甲醇:第一原理计算的启示

Cong Xi, Yixin Nie, Hongjuan Wang, Cunku Dong, Jiuhui Han, Xi-Wen Du
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摘要

催化二氧化碳加氢制甲醇为二氧化碳的循环利用提供了一条前景广阔的途径,从而提高了环境的可持续性。Cu/ZnO 早已被确定为该反应最有效的异相催化剂之一,但对其反应机理和活性位点的详细了解仍不全面。最近的研究进展凸显了缺陷在提高催化剂性能方面的关键作用,如 ZnCu 台阶和铜表面的堆叠断层。在此,我们通过对六种模型的第一原理表面模拟来探讨这一概念,这些模型具有不同的铜锌组合和特定的配位环境,并处于现实条件下。结果表明,具有扭结缺陷的 Cu/ZnO 催化剂,而不是表面 ZnCu 合金,在甲醇合成中表现出最佳活性。具体而言,研究结果表明了中间构型和速率决定步骤如何随表面结构的变化而变化,并通过电子结构计算揭示了扭结在促进 CO2 还原成甲醇过程中的作用。此外,研究还发现,在具有扭结的 Cu/ZnO 表面上,由 CO2 生成 CH3OH 的主要合成途径涉及反向水气变换和 CO 加氢,而不是甲酸盐途径。
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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Thermal Methanol Synthesis from CO2 Using Cu/ZnO Catalysts: Insights from First-Principles Calculations
Catalytic hydrogenation of carbon dioxide to methanol offers a promising avenue for recycling CO2, enhancing environmental sustainability. Cu/ZnO has long been identified as one of the most effective heterogeneous catalysts for this reaction, yet the detailed understanding of its reaction mechanism and active sites remains incomplete. Recent advances have highlighted the critical role of defects, such as ZnCu steps and stacking faults on Cu surfaces, in enhancing catalyst performance. Here this concept is explored through first-principles surface simulations of six models, featuring diverse Cu–Zn combinations and specific coordination environments under realistic conditions. It is revealed that Cu/ZnO catalysts with kink defects, rather than surface ZnCu alloys, exhibit optimal activity for methanol synthesis. Specifically, the findings demonstrate how intermediate configurations and rate-determining steps vary with changes in surface structure and reveal the role of the kink in promoting CO2 reduction to methanol through electronic structure calculation. Moreover, it is found that the predominant synthetic pathway for CH3OH from CO2 involves the reverse water gas shift and CO hydrogenation, rather than the formate route, on Cu/ZnO surfaces with kinks.
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