Dynamic Interconversion of Metal Active Site Ensembles in Zeolite Catalysis.

IF 7.6 2区 工程技术 Q1 CHEMISTRY, APPLIED
Siddarth H Krishna, Casey B Jones, Rajamani Gounder
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引用次数: 12

Abstract

Catalysis science is founded on understanding the structure, number, and reactivity of active sites. Kinetic models that consider active sites to be static and noninteracting entities are routinely successful in describing the behavior of heterogeneous catalysts. Yet, active site ensembles often restructure in response to their external environment and even during steady-state catalytic turnover, sometimes requiring non-mean-field kinetic treatments to describe distance-dependent interactions among sites. Such behavior is being recognized more frequently in modern catalysis research, with the advent of experimental methods to quantify turnover rates with increasing precision, an expanding arsenal of operando characterization tools, and computational descriptions of atomic structure and motion at chemical potentials and timescales increasingly relevant to reaction conditions. This review focuses on dynamic changes to metal active site ensembles on zeolite supports, which are silica-based crystalline materials substituted with Al that generate binding sites for isolated and low-nuclearity metal site ensembles. Metal sites can become solvated and mobilized during reaction, facilitating interactions among sites that change their nuclearity and function. Such intersite communication can be regulated by the zeolite support, resulting in non-single-site and potentially non-mean-field kinetic behavior arising from mechanisms of catalytic action that combine elements of those canonically associated with homogeneous and heterogeneous catalysis.We discuss recent literature examples that document dynamic active site behavior in metal-zeolites and outline methodologies to identify and interpret such behavior. We conclude with our outlook on future research directions to develop this evolving branch of catalysis science and harness it for practical applications.

沸石催化中金属活性位系群的动态相互转化。
催化科学是建立在了解活性位点的结构、数量和反应性的基础上的。考虑活性位点为静态和非相互作用实体的动力学模型通常成功地描述了多相催化剂的行为。然而,活性位点集合体经常根据外部环境甚至在稳态催化周转过程中进行重组,有时需要非平均场动力学处理来描述位点之间依赖距离的相互作用。这种行为在现代催化研究中得到了更频繁的认识,随着实验方法的出现,以越来越精确的方式量化周转率,操作分子表征工具的扩充,原子结构和运动的计算描述在化学势和时间尺度上与反应条件越来越相关。本文综述了沸石载体上金属活性位点群的动态变化,沸石载体是硅基晶体材料,取代铝,产生分离的低核金属位点群的结合位点。金属位在反应过程中被溶剂化和动员,促进了位之间的相互作用,改变了它们的核和功能。这种位点间的交流可以通过沸石载体来调节,从而导致非单位点和潜在的非平均场动力学行为,这是由催化作用机制引起的,它结合了那些通常与均相和非均相催化相关的元素。我们讨论了最近的文献例子,这些文献记录了金属沸石中的动态活性位点行为,并概述了识别和解释这种行为的方法。最后,我们展望了未来的研究方向,以发展这一不断发展的催化科学分支并将其用于实际应用。
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来源期刊
Annual review of chemical and biomolecular engineering
Annual review of chemical and biomolecular engineering CHEMISTRY, APPLIED-ENGINEERING, CHEMICAL
CiteScore
16.00
自引率
0.00%
发文量
25
期刊介绍: The Annual Review of Chemical and Biomolecular Engineering aims to provide a perspective on the broad field of chemical (and related) engineering. The journal draws from disciplines as diverse as biology, physics, and engineering, with development of chemical products and processes as the unifying theme.
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