Enhancing Room-Temperature CO Oxidation via Encapsulation of Bimetallic PtNi Clusters within Mesoporous Silicate-1 Catalyst

IF 6.1 1区化学 Q1 CHEMISTRY, INORGANIC & NUCLEAR

Inorganic Chemistry Frontiers Pub Date : 2025-05-10 DOI:10.1039/d5qi00781j

Ronghua Cui, Siyuan Yang, Lifeng Zhang, Xing Chen, Langli Luo

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Abstract

Bimetallic nanocatalysts have demonstrated superior performance in both thermal and electrochemical reactions, primarily due to their ability to modulate the structural and electronic properties of metal ensembles. In this study, we utilize a mesoporous Silicate-1 zeolite catalyst incorporating encapsulated PtNi clusters to systematically investigate the structural characteristic and electronic properties, and further correlated them with the catalytic performance for the room-temperature CO oxidation. Our findings reveal that the incorporation of Ni atoms significantly enhances oxygen adsorption and dissociation, thereby mitigating CO poisoning effects commonly observed in pure Pt clusters at low temperatures. This synergistic effect enables complete CO conversion at near-ambient temperatures (~30°C). These insights elucidate the fundamental mechanisms underlying the synergistic effects of alloy clusters in confined environments and highlight the potential for precise engineering of alloy cluster functionality for targeted catalytic applications.

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介孔硅酸盐-1催化剂包封双金属PtNi簇增强室温CO氧化

双金属纳米催化剂在热反应和电化学反应中表现出优异的性能，主要是由于它们能够调节金属体系的结构和电子性质。在本研究中，我们利用包封PtNi簇的介孔硅酸盐-1沸石催化剂系统地研究了其结构特征和电子性能，并进一步将其与室温CO氧化的催化性能联系起来。我们的研究结果表明，Ni原子的掺入显著增强了氧的吸附和解离，从而减轻了低温下纯Pt团簇中常见的CO中毒效应。这种协同效应可以在接近环境温度（~30°C）下实现完全的CO转化。这些见解阐明了在密闭环境中合金团簇协同效应的基本机制，并强调了合金团簇功能的精确工程用于靶向催化应用的潜力。

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