Jingguang G. Chen scite author profile

The active sites over commercial copper/zinc oxide/aluminum oxide (Cu/ZnO/AlO) catalysts for carbon dioxide (CO) hydrogenation to methanol, the Zn-Cu bimetallic sites or ZnO-Cu interfacial sites, have recently been the subject of intense debate. We report a direct comparison between the activity of ZnCu and ZnO/Cu model catalysts for methanol synthesis. By combining x-ray photoemission spectroscopy, density functional theory, and kinetic Monte Carlo simulations, we can identify and characterize the reactivity of each catalyst. Both experimental and theoretical results agree that ZnCu undergoes surface oxidation under the reaction conditions so that surface Zn transforms into ZnO and allows ZnCu to reach the activity of ZnO/Cu with the same Zn coverage. Our results highlight a synergy of Cu and ZnO at the interface that facilitates methanol synthesis via formate intermediates.

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A selective and efficient electrocatalyst for carbon dioxide reduction

Lü

et al. 2014

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Converting carbon dioxide to useful chemicals in a selective and efficient manner remains a major challenge in renewable and sustainable energy research. Silver is an interesting electrocatalyst owing to its capability of converting carbon dioxide to carbon monoxide selectively at room temperature; however, the traditional polycrystalline silver electrocatalyst requires a large overpotential. Here we report a nanoporous silver electrocatalyst that is able to electrochemically reduce carbon dioxide to carbon monoxide with approximately 92% selectivity at a rate (that is, current) over 3,000 times higher than its polycrystalline counterpart under moderate overpotentials of o0.50 V. The high activity is a result of a large electrochemical surface area (approximately 150 times larger) and intrinsically high activity (approximately 20 times higher) compared with polycrystalline silver. The intrinsically higher activity may be due to the greater stabilization of CO 2 À intermediates on the highly curved surface, resulting in smaller overpotentials needed to overcome the thermodynamic barrier.

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Beyond fossil fuel–driven nitrogen transformations

Chen

Crooks

Seefeldt

et al. 2018

Science

1,491

914

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Nitrogen is fundamental to all of life and many industrial processes. The interchange of nitrogen oxidation states in the industrial production of ammonia, nitric acid, and other commodity chemicals is largely powered by fossil fuels. A key goal of contemporary research in the field of nitrogen chemistry is to minimize the use of fossil fuels by developing more efficient heterogeneous, homogeneous, photo-, and electrocatalytic processes or by adapting the enzymatic processes underlying the natural nitrogen cycle. These approaches, as well as the challenges involved, are discussed in this Review.

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Correlating hydrogen oxidation and evolution activity on platinum at different pH with measured hydrogen binding energy

et al. 2015

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The hydrogen oxidation/evolution reactions are two of the most fundamental reactions in distributed renewable electrochemical energy conversion and storage systems. The identification of the reaction descriptor is therefore of critical importance for the rational catalyst design and development. Here we report the correlation between hydrogen oxidation/evolution activity and experimentally measured hydrogen binding energy for polycrystalline platinum examined in several buffer solutions in a wide range of electrolyte pH from 0 to 13. The hydrogen oxidation/evolution activity obtained using the rotating disk electrode method is found to decrease with the pH, while the hydrogen binding energy, obtained from cyclic voltammograms, linearly increases with the pH. Correlating the hydrogen oxidation/evolution activity to the hydrogen binding energy renders a monotonic decreasing hydrogen oxidation/evolution activity with the hydrogen binding energy, strongly supporting the hypothesis that hydrogen binding energy is the sole reaction descriptor for the hydrogen oxidation/evolution activity on monometallic platinum.

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Review of Pt-Based Bimetallic Catalysis: From Model Surfaces to Supported Catalysts

Porosoff²,

2012

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Catalytic reduction of CO₂ by H₂ for synthesis of CO, methanol and hydrocarbons: challenges and opportunities

Porosoff

Yan

Chen

2016

Energy Environ. Sci.

1,018

753

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Correlating the hydrogen evolution reaction activity in alkaline electrolytes with the hydrogen binding energy on monometallic surfaces

Sheng

Myint

Chen

et al. 2013

Energy Environ. Sci.

892

692

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The slow reaction kinetics of the hydrogen evolution and oxidation reactions (HER/HOR) on platinum in alkaline electrolytes hinders the development of alkaline electrolysers, solar hydrogen cells and alkaline fuel cells. A fundamental understanding of the exchange current density of the HER/HOR in alkaline media is critical for the search and design of highly active electrocatalysts. By studying the HER on a series of monometallic surfaces, we demonstrate that the HER exchange current density in alkaline solutions can be correlated with the calculated hydrogen binding energy (HBE) on the metal surfaces via a volcano type of relationship. The HER activity varies by several orders of magnitude from Pt at the peak of the plot to W and Au located on the bottom of each side of the plot, similar to the observation in acids. Such a correlation suggests that the HBE can be used as a descriptor for identifying electrocatalysts for HER/HOR in alkaline media, and that the HER exchange current density can be tuned by modifying the surface chemical properties.

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Tuning Selectivity of CO₂ Hydrogenation Reactions at the Metal/Oxide Interface

2017

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The chemical transformation of CO not only mitigates the anthropogenic CO emission into the Earth's atmosphere but also produces carbon compounds that can be used as precursors for the production of chemicals and fuels. The activation and conversion of CO can be achieved on multifunctional catalytic sites available at the metal/oxide interface by taking advantage of the synergy between the metal nanoparticles and oxide support. Herein, we look at the recent progress in mechanistic studies of CO hydrogenation to C1 (CO, CHOH, and CH) compounds on metal/oxide catalysts. On this basis, we are able to provide a better understanding of the complex reaction network, grasp the capability of manipulating structure and combination of metal and oxide at the interface in tuning selectivity, and identify the key descriptors to control the activity and, in particular, the selectivity of catalysts. Finally, we also discuss challenges and future research opportunities for tuning the selective conversion of CO on metal/oxide catalysts.

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Jingguang G. Chen

Active sites for CO ₂ hydrogenation to methanol on Cu/ZnO catalysts

A selective and efficient electrocatalyst for carbon dioxide reduction

Beyond fossil fuel–driven nitrogen transformations

Correlating hydrogen oxidation and evolution activity on platinum at different pH with measured hydrogen binding energy

Review of Pt-Based Bimetallic Catalysis: From Model Surfaces to Supported Catalysts

Catalytic reduction of CO₂ by H₂ for synthesis of CO, methanol and hydrocarbons: challenges and opportunities

Correlating the hydrogen evolution reaction activity in alkaline electrolytes with the hydrogen binding energy on monometallic surfaces

Tuning Selectivity of CO₂ Hydrogenation Reactions at the Metal/Oxide Interface

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Jingguang G. Chen

Active sites for CO 2 hydrogenation to methanol on Cu/ZnO catalysts

A selective and efficient electrocatalyst for carbon dioxide reduction

Beyond fossil fuel–driven nitrogen transformations

Correlating hydrogen oxidation and evolution activity on platinum at different pH with measured hydrogen binding energy

Review of Pt-Based Bimetallic Catalysis: From Model Surfaces to Supported Catalysts

Catalytic reduction of CO2 by H2 for synthesis of CO, methanol and hydrocarbons: challenges and opportunities

Correlating the hydrogen evolution reaction activity in alkaline electrolytes with the hydrogen binding energy on monometallic surfaces

Tuning Selectivity of CO2 Hydrogenation Reactions at the Metal/Oxide Interface

Contact Info

Product

Resources

About

Active sites for CO ₂ hydrogenation to methanol on Cu/ZnO catalysts

Catalytic reduction of CO₂ by H₂ for synthesis of CO, methanol and hydrocarbons: challenges and opportunities

Tuning Selectivity of CO₂ Hydrogenation Reactions at the Metal/Oxide Interface