Xiang Li scite author profile

The product selectivity of many heterogeneous electrocatalytic processes is profoundly affected by the liquid side of the electrocatalytic interface. The electrocatalytic reduction of CO to hydrocarbons on Cu electrodes is a prototypical example of such a process. However, probing the interactions of surface-bound intermediates with their liquid reaction environment poses a formidable experimental challenge. As a result, the molecular origins of the dependence of the product selectivity on the characteristics of the electrolyte are still poorly understood. Herein, we examined the chemical and electrostatic interactions of surfaceadsorbed CO with its liquid reaction environment. Using a series of quaternary alkyl ammonium cations (methyl 4 N + , ethyl 4 N + , propyl 4 N + , and butyl 4 N + ), we systematically tuned the properties of this environment. With differential electrochemical mass spectrometry (DEMS), we show that ethylene is produced in the presence of methyl 4 N + and ethyl 4 N + cations, whereas this product is not synthesized in propyl 4 N + -and butyl 4 N + -containing electrolytes. Surface-enhanced infrared absorption spectroscopy (SEIRAS) reveals that the cations do not block CO adsorption sites and that the cation-dependent interfacial electric field is too small to account for the observed changes in selectivity. However, SEIRAS shows that an intermolecular interaction between surface-adsorbed CO and interfacial water is disrupted in the presence of the two larger cations. This observation suggests that this interaction promotes the hydrogenation of surface-bound CO to ethylene. Our study provides a critical molecular-level insight into how interactions of surface species with the liquid reaction environment control the selectivity of this complex electrocatalytic process.hydrogen bonding | cation effects | electrocatalysis | carbon dioxide reduction | catalytic selectivity T he reaction environment profoundly impacts the kinetics of many chemical processes. Examples include the influence of the solvating environment on the rates of electron transfer (1), isomerization (2), peptide folding (3), and organic reactions (4), as well as the sensitivity of enzymatic catalysis to changes in the molecular structure of the active site (5). For a chemical process that can lead to multiple reaction products, solvent effects can impact the relative rates of product formation and therefore the product selectivity (6, 7). These effects, which can have complex energetic and/or dynamical origins (1,8,9), are fundamentally rooted in intermolecular interactions between the reactants and their environment. In the context of heterogeneous electrocatalysis, the reaction environment is asymmetric; i.e., reactants at the electrochemical interface are interacting with the solid electrode and the liquid electrolyte. Understanding the interactions of intermediates with their interfacial environment is essential for controlling the reaction paths of electrocatalytic processes that exhibit poor product selectivity.The reduc...

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Hydrodesulfurization of dibenzothiophene and its hydrogenated intermediates over bulk MoP

Bai

Wang

et al. 2012

Journal of Catalysis

131

100

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Deactivation and regeneration of a commercial SCR catalyst: Comparison with alkali metals and arsenic

Peng

et al. 2015

Applied Catalysis B: Environmental

181

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Nano‐Intermetallic AuCu₃ Catalyst for Oxygen Reduction Reaction: Performance and Mechanism

Zhang

Chen

et al. 2014

Small

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This paper introduces a new approach for catalyst design using the non-precious metal Cu as one of the catalytic active centers. This differs from previous studies that considered precious metals to be responsible for the catalytic reaction in precious alloys. Intermetallic AuCu3/C nanoparticles with a diameter of 3 nm were developed for the first time, with uniform dispersion and a narrow size distribution. The ca. 3 nm as-synthesised AuCu3/C showed superior catalytic performance for oxygen reduction reactions (ORR) in alkaline solutions, with comparable half-wave potential and 1.5 times mass current density of commercial Pt/C at 0.80 V (vs. reversible hydrogen electrode (RHE)). The advanced catalytic activities are mainly attributed to the synergetic effects of electro-active atomic Au and Cu on the particle surface, in which Cu helps to activate the O2 molecule and Au benefits OH(-) desorption. The excellent durability and methanol tolerance exhibited in alkaline solutions provide another advantage for AuCu3/C to be considered as a potential alternative cathode catalyst in alkaline fuel cells.

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Durable and Efficient Hollow Porous Oxide Spinel Microspheres for Oxygen Reduction

Wang

Liu

et al. 2018

Joule

195

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The oxygen reduction reaction performance of the hollow porous oxide spinel microspheres was investigated. The ZnMnCoO 4 possessed a high onset potential of 1.00 V and an outstanding durability in the alkaline solution. The electronic transition of Co 3+ ions was found to weaken the Co 3+ -OH bond and facilitate the O 2À /OH À displacement. Thus, it may offer promising potential for use as an effective catalyst with high oxygen reduction activity and durability in fuel cells and metal-air batteries, among other applications.

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Fiber-like nanostructured Ti4O7 used as durable fuel cell catalyst support in oxygen reduction catalysis

Yao

et al. 2012

J. Mater. Chem.

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Hydrodesulfurization of dibenzothiophene over siliceous MCM-41-supported nickel phosphide catalysts

Wang

Ruan

Teng

et al. 2005

Journal of Catalysis

110

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Xiang Li

Mastering the surface strain of platinum catalysts for efficient electrocatalysis

Hydrogen bonding steers the product selectivity of electrocatalytic CO reduction

Hydrodesulfurization of dibenzothiophene and its hydrogenated intermediates over bulk MoP

Deactivation and regeneration of a commercial SCR catalyst: Comparison with alkali metals and arsenic

Nano‐Intermetallic AuCu₃ Catalyst for Oxygen Reduction Reaction: Performance and Mechanism

Durable and Efficient Hollow Porous Oxide Spinel Microspheres for Oxygen Reduction

Fiber-like nanostructured Ti4O7 used as durable fuel cell catalyst support in oxygen reduction catalysis

Hydrodesulfurization of dibenzothiophene over siliceous MCM-41-supported nickel phosphide catalysts

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Xiang Li

Mastering the surface strain of platinum catalysts for efficient electrocatalysis

Hydrogen bonding steers the product selectivity of electrocatalytic CO reduction

Hydrodesulfurization of dibenzothiophene and its hydrogenated intermediates over bulk MoP

Deactivation and regeneration of a commercial SCR catalyst: Comparison with alkali metals and arsenic

Nano‐Intermetallic AuCu3 Catalyst for Oxygen Reduction Reaction: Performance and Mechanism

Durable and Efficient Hollow Porous Oxide Spinel Microspheres for Oxygen Reduction

Fiber-like nanostructured Ti4O7 used as durable fuel cell catalyst support in oxygen reduction catalysis

Hydrodesulfurization of dibenzothiophene over siliceous MCM-41-supported nickel phosphide catalysts

Contact Info

Product

Resources

About

Nano‐Intermetallic AuCu₃ Catalyst for Oxygen Reduction Reaction: Performance and Mechanism