Jan Fingerhut, Loïc Lecroart, Michael Schwarzer, Stefan Hörandl, Dmitriy Borodin, Alexander Kandratsenka, Theofanis N. Kitsopoulos, Daniel J. Auerbach and Alec M. Wodtke
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引用次数: 0
Abstract
Uncovering the role of reaction intermediates is crucial to developing an understanding of heterogeneous catalysis because catalytic reactions often involve complex networks of elementary steps. Identifying the reaction intermediates is often difficult because their short lifetimes and low concentrations make it difficult to observe them with surface sensitive spectroscopic techniques. In this paper we report a different approach to identify intermediates for the formic acid decomposition reaction on Pd(111) and Pd(332) based on accurate measurements of isotopologue specific thermal reaction rates. At low surface temperatures (∼400 K) CO2 formation is the major reaction pathway. The CO2 kinetic data show this occurs via two temporally resolved reaction processes. Thus, there must be two parallel pathways which we attribute to the participation of two intermediate species in the reaction. Isotopic substitution reveals large and isotopologue specific kinetic isotope effects that allow us to identify the two key intermediates as bidentate formate and carboxyl. The decomposition of the bidentate formate is substantially slower than that of carboxyl. On Pd(332), at high surface temperatures (643 K to 693 K) we observe both CO and CO2 production. The observation of CO formation reinforces the conclusion of calculations that suggest the carboxyl intermediate plays a major role in the water–gas shift reaction, where carboxyl exhibits temperature dependent branching between CO2 and CO.
由于催化反应通常涉及复杂的基本步骤网络,因此揭示反应中间产物的作用对于理解异相催化反应至关重要。遗憾的是,反应过程中出现的中间产物寿命短、浓度低,因此用表面敏感光谱观测和识别它们往往具有实验挑战性。在本文中,我们报告了一种基于钯(111)和钯(332)上甲酸分解的同位素特定热反应速率来识别中间产物的不同方法。在低表面温度(约 400 K)下,二氧化碳的形成是这两个面上的主要反应途径。动力学数据显示,这是通过两个时间分辨的反应过程发生的,这表明一定有两条平行的途径,强烈暗示有两个中间物种参与其中。同位素置换揭示了巨大的、特定于同位素的动力学同位素效应,使我们能够确定这两种中间体为双叉甲酸酯和羧基。我们证明,双叉甲酸酯中间体分解缓慢,而羧基中间体分解迅速。在较高的表面温度(643 K 至 693 K)下,我们观察到 CO 在 Pd(332) 上形成。这一观察结果与基于密度泛函理论的提议相吻合,即羧基中间体在水气转换反应(WGSR)中发挥了重要作用,它在 CO 和 H2O 形成 CO2 的过程中起着桥梁作用。