Carbon monoxide hydrogenation over iron oxide, subjected to shear deformation under high pressure: role of vacancies

Applied Catalysis Pub Date : 1991-11-12 DOI:10.1016/0166-9834(91)80108-9

O.S. Morozova *, yu.v. Maksimov, D.P. Shashkin, P.A. Shirjaev, V.V. Matveyev, V.A. Zhorin, O.V. Krylov, G.N. Krjukova

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引用次数: 12

Abstract

The formation of catalytically active structures m both “unloaded” polycrystalline α-Fe₂O₃ and “loaded”, i.e. subjected to shear deformation under high pressure (SD+HP), was studied by “in situ” X-ray diffraction in an atmosphere of carbon monoxide and hydrogen, by transmission electron microscopy and by Mössbauer spectroscopy. Two main stages were observed in the activation process which correspond to different degrees of iron oxide reduction. The first stage (270–290°C ) was the reduction to nonstoichiometric magnetite, accompanied by carbon monoxide hydrogenation to saturated hydrocarbons. The second stage ( > 300 °C ) was the deep reduction to nonstoichiometric magnetite and clusters of iron carbide, accompanied by the appearance of unsaturated hydrocarbons. The overall catalytic activity was shown to be a function of both total length of spinel-carbide phase boundaries and the topology of the interface. In the case of the “unloaded” sample the formation of intercalated particles of carbide phase with alternating spinel-carbide layers led to a higher activity than that of the “loaded” one. Loose aggregates of carbide particles formed on the “loaded” sample block up active centres on the spinel surface and reduce the total activity. The nature of active centres on the surface of nonstoichiometric magnetite is discussed.

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一氧化碳氢化过氧化铁，在高压下受到剪切变形:空位的作用

在一氧化碳和氢气气氛中，通过x射线原位衍射、透射电镜和Mössbauer光谱研究了α-Fe2O3多晶在“空载”和“加载”(即在高压(SD+HP)下剪切变形)下催化活性结构的形成。在活化过程中观察到两个主要阶段，对应于不同程度的氧化铁还原。第一阶段(270-290℃)是还原为非化学计量磁铁矿，伴随着一氧化碳加氢生成饱和烃。第二阶段(>300°C)深度还原为非化学计量磁铁矿和铁碳化物簇，并伴有不饱和烃的出现。总的催化活性是尖晶石-碳化物相边界总长度和界面拓扑结构的函数。在“未加载”样品中，碳化物相的插层颗粒与尖晶石-碳化物层交替形成，导致活性高于“加载”样品。在“负载”样品上形成的松散的碳化物颗粒聚集体阻塞了尖晶石表面的活性中心，降低了总活性。讨论了非化学计量磁铁矿表面活性中心的性质。

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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Applied Catalysis

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