In Situ Visualization of Lattice-Coherent Phase Oscillations and Active Brownian Motion of a Copper Catalyst During Hydrogen Oxidation.

IF 16.9 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Angewandte Chemie International Edition Pub Date : 2025-10-20 DOI:10.1002/anie.202515820

Yongzhao Wang,Chao Zhao,Panpan Liu,Shengnan Yue,Yuan Wen,Zhaoying Wang,Tongtong Gao,Praveen Chandramathy Surendran,Travis Jones,Feng Ding,Xing Huang

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引用次数: 0

Abstract

Structural dynamics govern the catalytic activity of metal nanoparticles (NPs), yet their atomic-scale mechanisms remain unclear. Using in situ transmission electron microscopy, we reveal redox-driven lattice-coherent Cu↔Cu2O phase oscillations in individual Cu NPs during hydrogen oxidation conditions. These oscillations generate active Brownian particles, wherein asymmetric H2 oxidation leads to directional motion that results in particle collisions and sintering. Crucially, the same active Brownian motion also triggers particle splitting, counteracting surface area loss and deactivation. Such active matter behavior arises from the formation of a head-tail morphology at critical H2:O2 ratios (e.g., 5:1), featuring a metallic-rich head and an oxide-dominated tail, with their volumetric balance dynamically shifting through competitive oxidation-reduction cycles. Quantitative analysis establishes a direct correlation between migration velocity and redox dynamics, revealing that the oxidation process significantly enhances particle mobility while the followed reduction process slows the velocity. Molecular dynamics (MD) simulations demonstrate that particle elongation and oxide tail fragmentation, accompanying particle migration, can be explained by asymmetric adhesion forces between the metallic/oxide phases and the silicon nitride support, alongside the redox reactions occurring on the particles. This work provides atomic-scale insights into catalyst dynamics under operando redox conditions, offering foundational knowledge for designing stable, high-performance catalytic systems.

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氢氧化过程中铜催化剂晶格相干相振荡和活跃布朗运动的原位可视化。

结构动力学控制了金属纳米颗粒（NPs）的催化活性，但其原子尺度机制尚不清楚。使用原位透射电子显微镜，我们揭示了氢氧化条件下单个Cu NPs中氧化还原驱动的晶格相干Cu↔Cu2O相振荡。这些振荡产生活跃的布朗粒子，其中不对称的H2氧化导致定向运动，导致粒子碰撞和烧结。至关重要的是，同样活跃的布朗运动也会引发粒子分裂，抵消表面积损失和失活。这种活性物质行为源于在临界H2:O2比（例如5:1）下形成的首尾形态，其特征是富金属的头部和以氧化物为主的尾部，它们的体积平衡在竞争性氧化还原循环中动态变化。定量分析建立了迁移速度与氧化还原动力学之间的直接关系，揭示了氧化过程显著提高了颗粒迁移率，而随后的还原过程减慢了速度。分子动力学（MD）模拟表明，金属/氧化物相与氮化硅载体之间的不对称附着力以及颗粒上发生的氧化还原反应可以解释颗粒伸长和氧化物尾部断裂以及颗粒迁移。这项工作提供了原子尺度上对氧化还原条件下催化剂动力学的见解，为设计稳定、高性能的催化系统提供了基础知识。

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

Angewandte Chemie International Edition 化学-化学综合

CiteScore

26.60

自引率

6.60%

发文量

3549

审稿时长

1.5 months

期刊介绍： Angewandte Chemie, a journal of the German Chemical Society (GDCh), maintains a leading position among scholarly journals in general chemistry with an impressive Impact Factor of 16.6 (2022 Journal Citation Reports, Clarivate, 2023). Published weekly in a reader-friendly format, it features new articles almost every day. Established in 1887, Angewandte Chemie is a prominent chemistry journal, offering a dynamic blend of Review-type articles, Highlights, Communications, and Research Articles on a weekly basis, making it unique in the field.