Probing the structure–property relationships of supported copper oxide nanoclusters for methane activation†

EES catalysis Pub Date : 2023-11-16 DOI:10.1039/D3EY00234A
Xijun Wang, Kaihang Shi, Anyang Peng and Randall Q. Snurr
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Abstract

Supported metal oxide nanoclusters (MeO-NCs) have gained significant attention for their remarkable versatility in various energy and sustainability applications. Despite rapid advancements in atomic-scale synthesis and characterization techniques, the rational design of MeO-NCs with desired catalytic properties remains challenging. This challenge arises from the elusive and difficult-to-quantify structure-catalytic property relationships, particularly in the case of amorphous nanoclusters. Exploiting first-principles calculations at the density functional theory (DFT) level, we conducted a systematic investigation into the growth, geometries, and catalytic performance of a series of tetra-copper oxide nanoclusters (Cu4O-NCs) for methane activation. Focusing on the most representative geometries, we applied machine learning to extract two physically insightful descriptors involving the spin density, the p-band center of the oxygen site, and the d-band center of adjacent Cu sites. These descriptors enable us to predict free energy barriers associated with both the homolytic and heterolytic mechanisms of methane activation. This descriptor-driven approach enables rapid and intuitive prediction of the preferred reaction mechanism. Our findings lay a solid foundation for future advancements in catalysts based on amorphous nanoclusters and provide valuable insights into the mechanistic landscape of methane activation.

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负载型氧化铜纳米团簇对甲烷活化的构效关系探讨
负载型金属氧化物纳米团簇(MeO-NCs)因其在各种能源和可持续性应用中的多功能性而受到广泛关注。尽管原子尺度合成和表征技术取得了快速发展,但具有理想催化性能的MeO-NCs的合理设计仍然具有挑战性。这一挑战源于难以捉摸和难以量化的结构-催化性质关系,特别是在非晶纳米团簇的情况下。利用密度泛函理论(DFT)水平的第一性原理计算,我们对一系列四氧化铜纳米团簇(cu40 - ncs)的生长、几何形状和甲烷活化的催化性能进行了系统的研究。专注于最具代表性的几何形状,我们应用机器学习提取了两个物理上有洞察力的描述符,包括自旋密度、氧位点的p带中心和相邻Cu位点的d带中心。这些描述符使我们能够预测与甲烷活化的均溶和异溶机制相关的自由能垒。这种描述符驱动的方法能够快速和直观地预测首选反应机制。我们的发现为未来基于非晶纳米团簇的催化剂的发展奠定了坚实的基础,并为甲烷活化的机制景观提供了有价值的见解。
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Back cover Correction: High photocatalytic yield in the non-oxidative coupling of methane using a Pd–TiO2 nanomembrane gas flow-through reactor Embedding the intermetallic Pt5Ce alloy in mesopores through Pt–C coordination layer interactions as a stable electrocatalyst for the oxygen reduction reaction† Efficient CO2-to-CO conversion in dye-sensitized photocatalytic systems enabled by electrostatically-driven catalyst binding† Green energy driven methane conversion under mild conditions
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