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化学进展  2013 

铈铁复合氧化物的结构特征及其催化应用

DOI: 10.7536/PC121146, PP. 1691-1702

Keywords: 铈铁复合氧化物,氧化铈,氧化铁,固溶体,氧空位,催化,交互作用

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Abstract:

氧化铈(CeO2)是一种重要的催化材料,在环境催化和催化氧化等诸多领域表现出了出色的催化性能。将其他金属离子引入氧化铈晶格通过电荷平衡原理诱导产生丰富的氧空位,是提高氧化铈催化性能的有效方法。当Fe3+进入CeO2晶格时,由于其离子半径较小,可同时形成取代和间隙两类固溶体,取代与间隙位Fe3+的摩尔比决定着氧空位的浓度,这使铈铁复合氧化物上的氧空位浓度极具调变性。另外,由于氧化铁本身亦对某些反应具有催化活性,游离的氧化铁与氧化铈颗粒间形成的特殊界面也表现出了优异的催化特性。铈铁间多重的协同作用使这类复合氧化物具有较高的研究和使用价值。本文介绍了铁离子在氧化铈中的固溶度和氧空位调变性等铈铁复合氧化物的结构特点,探讨了该材料的结构对其制备条件的敏感性,概述了其在催化领域的应用,并讨论了铈铁交互作用在催化过程中的作用。结合本课题组的一些研究成果,指出了铈铁材料尚未解决的一些关键问题和可能的研究方向。

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