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13 results on '"Jan Rossmeisl"'

2. Electrochemical carbonyl reduction on single-site M–N–C catalysts

Author

Wen Ju, Alexander Bagger, Nastaran Ranjbar Saharie, Sebastian Möhle, Jingyi Wang, Frederic Jaouen, Jan Rossmeisl, and Peter Strasser

Subjects
Chemistry, QD1-999
Abstract

Abstract Electrochemical conversion of organic compounds holds promise for advancing sustainable synthesis and catalysis. This study explored electrochemical carbonyl hydrogenation on single-site M–N–C (Metal Nitrogen-doped Carbon) catalysts using formaldehyde, acetaldehyde, and acetone as model reactants. We strive to correlate and understand the selectivity dependence on the nature of the metal centers. Density Functional Theory calculations revealed similar binding energetics for carbonyl groups through oxygen-down or carbon-down adsorption due to oxygen and carbon scaling. Fe–N–C exhibited specific oxyphilicity and could selectively reduce aldehydes to hydrocarbons. By contrast, the carbophilic Co–N–C selectively converted acetaldehyde and acetone to ethanol and 2-propanol, respectively. We claim that the oxyphilicity of the active sites and consequent adsorption geometry (oxygen-down vs. carbon-down) are crucial in controlling product selectivity. These findings offer mechanistic insights into electrochemical carbonyl hydrogenation and can guide the development of efficient and sustainable electrocatalytic valorization of biomass-derived compounds.

Published
2023
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3. Steering carbon dioxide reduction toward C–C coupling using copper electrodes modified with porous molecular films

Author

Siqi Zhao, Oliver Christensen, Zhaozong Sun, Hongqing Liang, Alexander Bagger, Kristian Torbensen, Pegah Nazari, Jeppe Vang Lauritsen, Steen Uttrup Pedersen, Jan Rossmeisl, and Kim Daasbjerg

Subjects
Science
Abstract

This study explores how the activity and selectivity of Cu electrodes for CO2 reduction can be tuned with organic films of different porosity and thickness. As a result, the films increase the local CO partial pressures and surface coverages.

Published
2023
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4. Morphology and mechanism of highly selective Cu(II) oxide nanosheet catalysts for carbon dioxide electroreduction

Author

Xingli Wang, Katharina Klingan, Malte Klingenhof, Tim Möller, Jorge Ferreira de Araújo, Isaac Martens, Alexander Bagger, Shan Jiang, Jan Rossmeisl, Holger Dau, and Peter Strasser

Subjects
Science
Abstract

Copper oxides (CuO) can selectively catalyze the electrochemical reduction of CO2 to hydrocarbons and oxygenates. Here, the authors study the activity and morphological evolution of 2D CuO nanosheets under applied electrode potentials to conclude the primacy of dendritic shapes and involvement of a new coupling pathway.

Published
2021
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5. What Atomic Positions Determines Reactivity of a Surface? Long‐Range, Directional Ligand Effects in Metallic Alloys

Author

Christian M. Clausen, Thomas A. A. Batchelor, Jack K. Pedersen, and Jan Rossmeisl

Subjects
adsorption energy predictions, electrocatalysis, high‐entropy alloys, ligand effects, oxygen reduction reaction, Science
Abstract

Abstract Ligand and strain effects can tune the adsorption energy of key reaction intermediates on a catalyst surface to speed up rate‐limiting steps of the reaction. As novel fields like high‐entropy alloys emerge, understanding these effects on the atomic structure level is paramount: What atoms near the binding site determine the reactivity of the alloy surface? By statistical analysis of 2000 density functional theory calculations and subsequent host/guest calculations, it is shown that three atomic positions in the third layer of an fcc(111) metallic structure fourth‐nearest to the adsorption site display significantly increased influence on reactivity over any second or third nearest atomic positions. Subsequently observed in multiple facets and host metals, the effect cannot be explained simply through the d‐band model or a valence configuration model but rather by favorable directions of interaction determined by lattice geometry and the valence difference between host and guest elements. These results advance the general understanding of how the electronic interaction of different elements affect adsorbate–surface interactions and will contribute to design principles for rational catalyst discovery of better, more stable and energy efficient catalysts to be employed in energy conversion, fuel cell technologies, and industrial processes.

Published
2021
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6. Understanding activity and selectivity of metal-nitrogen-doped carbon catalysts for electrochemical reduction of CO2

Author

Wen Ju, Alexander Bagger, Guang-Ping Hao, Ana Sofia Varela, Ilya Sinev, Volodymyr Bon, Beatriz Roldan Cuenya, Stefan Kaskel, Jan Rossmeisl, and Peter Strasser

Subjects
Science
Abstract

Inexpensive and selective electrocatalysts for CO2 reduction hold promise for sustainable fuel production. Here, the authors report N-coordinated, non-noble metal-doped porous carbons as efficient and selective electrocatalysts for CO2 to CO conversion.

Published
2017
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8. Surface Pourbaix diagrams and oxygen reduction activity of Pt, Ag and Ni(111) surfaces studied by DFT.

Author

Heine A. Hansen, Jan Rossmeisl, and Jens K. Nørskov

Abstract

Based on density functional theory calculations we investigate the electrochemically most stable surface structures as a function of pH and electrostatic potential for Pt(111), Ag(111) and Ni(111), and we construct surface Pourbaix diagrams. We study the oxygen reduction reaction (ORR) on the different surface structures and calculate the free energy of the intermediates. We estimate their catalytic activity for ORR by determining the highest potential at which all ORR reaction steps reduce the free energy. We obtain self-consistency in the sense that the surface is stable under the potential at which that particular surface can perform ORR. Using the self consistent surfaces, the activity of the very reactive Ni surface changes dramatically, whereas the activity of the more noble catalysts Pt and Ag remains unchanged. The reason for this difference is the oxidation of the reactive surface. Oxygen absorbed on the surface shifts the reactivity towards the weak binding region, which in turn increases the activity. The oxidation state of the surface and the ORR potential are constant versus the reversible hydrogen electrode (RHE). The dissolution potential in acidic solution, on the other hand, is constant vs. the standard hydrogen electrode (SHE). For Ag, this means that where the potential for dissolution and ORR are about the same at pH = 0, Ag becomes more stable relative to RHE as pH is increased. Hence the pH dependent stability offers an explanation for the possible use of Ag in alkaline fuel cell cathodes. [ABSTRACT FROM AUTHOR]

Published
2008
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9. Density functional theory calculations for the hydrogen evolution reaction in an electrochemical double layer on the Pt(111) electrode.

Author

Egill Skúlason, Gustav S. Karlberg, Jan Rossmeisl, Thomas Bligaard, Jeff Greeley, Hannes Jónsson, and Jens K. Nørskov

Abstract

We present results of density functional theory calculations on a Pt(111) slab with a bilayer of water, solvated protons in the water layer, and excess electrons in the metal surface. In this way we model the electrochemical double layer at a platinum electrode. By varying the number of protons/electrons in the double layer we investigate the system as a function of the electrode potential. We study the elementary processes involved in the hydrogen evolution reaction, 2(H+ + e−) → H2, and determine the activation energy and predominant reaction mechanism as a function of electrode potential. We confirm by explicit calculations the notion that the variation of the activation barrier with potential can be viewed as a manifestation of the Brønsted–Evans–Polanyi-type relationship between activation energy and reaction energy found throughout surface chemistry. [ABSTRACT FROM AUTHOR]

Published
2007
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10. Calculated Phase Diagrams for the Electrochemical Oxidation and Reduction of Water over Pt(111).

Author

Jan Rossmeisl, Jens K. Nørskov, Christopher D. Taylor, Michael J. Janik, and Matthew Neurock

Subjects
*ELECTROCHEMICAL analysis, *OXIDATION, *DENSITY functionals, *CATHODE rays, *NONMETALS
Abstract

Ab initio density functional theory is used to calculate the electrochemical phase diagram for the oxidation and reduction of water over the Pt(111) surface. Three different schemes proposed in the literature are used to calculate the potential-dependent free energy of hydrogen, water, hydroxyl, and oxygen species adsorbed to the surface. Despite the different foundations for the models and their different complexity, they can be directly related to one another through a systematic Taylor series expansion of the Nernst equation. The simplest model, which includes the potential only as a shift in the chemical potential of the electrons, accounts very well for the thermochemical features determining the phase-diagram. [ABSTRACT FROM AUTHOR]

Published
2006
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11. Changing the Activity of Electrocatalysts for Oxygen Reduction by Tuning the Surface Electronic StructureThis work was supported by the Director, Office of Science, Office of Basic Energy Sciences, Division of Materials Sciences, US Department of Energy (contract no. DE-AC03–76SF00098), by The Danish Research Council through the NABIIT program, and by the Danish Center for Scientific Computing (grant no. HDW-1103-06). J.G. acknowledges a H. C. Ørsted Postdoctoral Fellowship from the Technical University of Denmark. N.M.M. acknowledges support from the US Department of Energy under contract W-31-109-ENG-38.

Author

Vojislav Stamenkovic, Bongjin Simon Mun, Karl J. J. Mayrhofer, Philip N. Ross, Nenad M. Markovic, Jan Rossmeisl, Jeff Greeley, and Jens K. Nørskov

Published
2006
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