热化学异相催化的无线电位仪

Neil, Razdan, Karl, Westendorff, Yogesh, Surendranath
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引用次数: 0

摘要

与液体介质接触的催化剂表面会发生自发的电荷转移反应,使固液界面产生电极化。因此,表面的电化学势 Ecat 是定义催化自由能谱的关键参数。对于支撑在导电材料上并与外部电路连接的催化剂,Ecat 很容易测量,但对于绝大多数支撑在电绝缘体上的热化学催化剂,Ecat 却很难量化。这种测量差距阻碍了人们对电化学极化在热化学催化中作用的统一认识。在此,我们开发了一种方法,通过引入小浓度的氧化还原活性分子,在分散催化剂和惰性传感电极之间建立无线电连接,从而量化支撑在绝缘体上的金属催化剂的 Ecat。我们通过量化在水和乙腈溶剂中涉及 H2 或 O2 的催化反应过程中的 Ecat 验证了这种方法。利用这种方法,我们揭示了 SiO2- 和 Al2O3- 与 TiO2- 支持的铂催化剂进行有氧甲酸氧化催化时的不同速率-电位标度。我们在此开发的方法可以广泛地研究电化学极化在热化学催化中的作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wireless potentiometry of thermochemical heterogeneous catalysis
Catalyst surfaces in contact with liquid media are subject to spontaneous charge transfer reactions that electrically polarize the solid-liquid interface. Consequently, the electrochemical potential, Ecat, of the surface is a critical parameter that defines the free-energy landscape of catalysis. Ecat can be readily measured for a catalyst supported on a conductive material and wired to an external circuit but is difficult to quantify for the vast majority of thermochemical catalysts that are supported on electrical insulators. This measurement gap has impeded a unifying understanding of the role of electrochemical polarization in thermochemical catalysis. Herein, we develop a methodology for quantifying Ecat of metal catalysts supported on insulators by introducing a small concentration of a redox-active molecule to establish a wireless electrical connection between the dispersed catalyst and an inert sensing electrode. We validate this approach by quantifying Ecat during catalytic reactions involving H2 or O2 in water and acetonitrile solvent. Using this methodology, we expose distinct rate-potential scalings for aerobic formic acid oxidation catalysis on SiO2- and Al2O3- versus TiO2-supported Pt catalysts. The methodology we develop herein enables the broad-based investigation of the role of electrochemical polarization in thermochemical catalysis.
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