氧化还原催化剂的活性中心

G. Kosmambetova
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引用次数: 0

摘要

从泰勒的工作到对催化系统复杂和多层次结构的现代理解,考虑了固体相催化剂活性位点结构表征的发展。分析了深度转化、选择性转化和优先转化氧化还原过程中催化剂活性中心的主要类型。结果表明,对于每种类型的反应,无论催化剂组分的化学性质如何,活性中心的结构都具有一定的共同特征,并决定了转化的方向。特别关注由隔离活性中心形成的活性位点的结构(“单位点隔离”),它允许在目标产物的获得和新反应的实施方向上实现催化过程的高选择性。其中,甲烷氧化羰基化制乙酸的反应首次在气相中进行,以分子氧为氧化剂,催化剂的活性中心是由硒氯化铑组成的分离的Rh3+离子。另一种类型的活性中心是由位于晶体晶界上的原子呈现的,这是由于催化剂组分之间的界面相互作用而产生的:载体、活性组分、改性剂,以及团聚体系中均匀纳米晶体之间的晶界。结果表明,催化剂的空间结构决定了催化剂活性中心的可用性,这对催化剂的催化性能起着重要的作用。沸石、有机金属化合物(MOF)、活性中心位于腔通道内的介结构氧化物都是这种催化系统的例子。先进催化剂领域研究的主要策略是开发催化材料的合成方法,以提供形成作为最大数量的活性中心,因此它们可用于试剂和随后转化为目标产物。设计这样的系统是一项复杂的任务,其基础是建立催化材料的组成、结构和尺寸特征之间的相关性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Active centers of redox catalysts
The development of representations about the active site structure of solid-phase catalysts, ranging from the work of H. Taylor to a modern understanding of the complex and multi-level structure of catalytic systems, is considered. The main types of active centers of catalysts for redox processes of deep, selective, and preferential conversion are analyzed. It is shown that for each type of reaction, regardless of the chemical nature of the catalyst components, the structure of the active center is characterized by certain common features and determines the direction of conversion. Particular attention is paid to the structure of active sites formed by the type of an isolated active center ("Single Site Isolation"), which allows achieving high selectivity of catalytic processes in the direction of target products obtaining and implementation of new reactions. In particular, the reaction of methane oxidative carbonylation to acetic acid was first carried out in a gas phase using molecular oxygen as an oxidant and catalysts whose active centers were presented by isolated Rh3+ ions in the composition of rhodium selenochloride. A separate type of active center is presented by atoms located on the grain boundaries of crystallites, which arise as a result of interfacing interaction between catalyst components: support, active component, modificator, as well as grain boundaries between homogeneous nanocrystallites in agglomerated systems. It is shown that an important role in the manifestation of catalytic properties plays the availability of an active center for reagents, caused by the spatial structure of catalysts. Zeolites, organometallic compounds (MOF), mesostructural oxides in which active centers are located inside the cavity channels are examples of such catalytic systems. The main strategy of research in the field of advanced catalysts is aimed at developing methods for the synthesis of catalytic materials, which provide formation as the maximum number of active centers, so their availability for reagents and subsequent conversion to target products. Designing such systems is a complex task, based on establishing a correlation between composition, structure, and size characteristics of catalytic materials.
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