Your search keyword '"Marks, Kess"' showing total 4 results

1. Naphthalene Dehydrogenation on Ni(111) in the Presence of Chemisorbed Oxygen and Nickel Oxide.

Author

Marks, Kess, Erbing, Axel, Hohmann, Lea, Chien, Tzu-En, Yazdi, Milad Ghadami, Muntwiler, Matthias, Hansson, Tony, Engvall, Klas, Harding, Dan J., Öström, Henrik, Odelius, Michael, and Göthelid, Mats

Subjects

NICKEL oxides, NICKEL oxide, PHOTON upconversion, NAPHTHALENE, DEHYDROGENATION, PHOTOELECTRON spectroscopy

Abstract

Catalyst passivation through carbon poisoning is a common and costly problem as it reduces the lifetime and performance of the catalyst. Adding oxygen to the feed stream could reduce poisoning but may also affect the activity negatively. We have studied the dehydrogenation, decomposition, and desorption of naphthalene co-adsorbed with oxygen on Ni(111) by combining temperature-programmed desorption (TPD), sum frequency generation spectroscopy (SFG), photoelectron spectroscopy (PES), and density functional theory (DFT). Chemisorbed oxygen reduces the sticking of naphthalene and shifts H2 production and desorption to higher temperatures by blocking active Ni sites. Oxygen increases the production of CO and reduces carbon residues on the surface. Chemisorbed oxygen is readily removed when naphthalene is decomposed. Oxide passivates the surface and reduces the sticking coefficient. But it also increases the production of CO dramatically and reduces the carbon residues. Ni2O3 is more active than NiO. [ABSTRACT FROM AUTHOR]

Published

2024

2. Investigation of the surface species during temperature dependent dehydrogenation of naphthalene on Ni(111).

Author

Marks, Kess, Yazdi, Milad Ghadami, Piskorz, Witold, Simonov, Konstantin, Stefanuik, Robert, Sostina, Daria, Guarnaccio, Ambra, Ovsyannikov, Ruslan, Giangrisostomi, Erika, Sassa, Yasmine, Bachellier, Nicolas, Muntwiler, Matthias, Johansson, Fredrik O. L., Lindblad, Andreas, Hansson, Tony, Kotarba, Andrzej, Engvall, Klas, Göthelid, Mats, Harding, Dan J., and Öström, Henrik

Subjects

DEHYDROGENATION, CATALYTIC dehydrogenation, TUNNELING spectroscopy, NAPHTHALENE, SCANNING tunneling microscopy, X-ray photoelectron spectroscopy, DENSITY functional theory

Abstract

The temperature dependent dehydrogenation of naphthalene on Ni(111) has been investigated using vibrational sum-frequency generation spectroscopy, X-ray photoelectron spectroscopy, scanning tunneling microscopy, and density functional theory with the aim of discerning the reaction mechanism and the intermediates on the surface. At 110 K, multiple layers of naphthalene adsorb on Ni(111); the first layer is a flat lying chemisorbed monolayer, whereas the next layer(s) consist of physisorbed naphthalene. The aromaticity of the carbon rings in the first layer is reduced due to bonding to the surface Ni-atoms. Heating at 200 K causes desorption of the multilayers. At 360 K, the chemisorbed naphthalene monolayer starts dehydrogenating and the geometry of the molecules changes as the dehydrogenated carbon atoms coordinate to the nickel surface; thus, the molecule tilts with respect to the surface, recovering some of its original aromaticity. This effect peaks at 400 K and coincides with hydrogen desorption. Increasing the temperature leads to further dehydrogenation and production of H2 gas, as well as the formation of carbidic and graphitic surface carbon. [ABSTRACT FROM AUTHOR]

Published

2019

3. Atom-specific activation in CO oxidation.

Author

Schreck, Simon, Diesen, Elias, LaRue, Jerry, Ogasawara, Hirohito, Marks, Kess, Nordlund, Dennis, Weston, Matthew, Beye, Martin, Cavalca, Filippo, Perakis, Fivos, Sellberg, Jonas, Eilert, André, Kim, Kyung Hwan, Coslovich, Giacomo, Coffee, Ryan, Krzywinski, Jacek, Reid, Alex, Moeller, Stefan, Lutman, Alberto, and Öström, Henrik

Subjects

CARBON dioxide, X-ray absorption, FEMTOSECOND lasers, CHEMICAL reactions, X-ray spectroscopy, COHERENCE (Physics)

Abstract

We report on atom-specific activation of CO oxidation on Ru(0001) via resonant X-ray excitation. We show that resonant 1s core-level excitation of atomically adsorbed oxygen in the co-adsorbed phase of CO and oxygen directly drives CO oxidation. We separate this direct resonant channel from indirectly driven oxidation via X-ray induced substrate heating. Based on density functional theory calculations, we identify the valence-excited state created by the Auger decay as the driving electronic state for direct CO oxidation. We utilized the fresh-slice multi-pulse mode at the Linac Coherent Light Source that provided time-overlapped and 30 fs delayed pairs of soft X-ray pulses and discuss the prospects of femtosecond X-ray pump X-ray spectroscopy probe, as well as X-ray two-pulse correlation measurements for fundamental investigations of chemical reactions via selective X-ray excitation. [ABSTRACT FROM AUTHOR]

Published

2018

4. Dehydrogenation of methanol on Cu2O(100) and (111).

Author

Besharat, Zahra, Stenlid, Joakim Halldin, Soldemo, Markus, Marks, Kess, Önsten, Anneli, Johnson, Magnus, Öström, Henrik, Weissenrieder, Jonas, Brinck, Tore, and Göthelid, Mats

Subjects

DEHYDROGENATION, METHANOL, COPPER oxide, PHOTOELECTRON spectroscopy, DENSITY functional theory

Abstract

Adsorption and desorption of methanol on the (111) and (100) surfaces of Cu2O have been studied using high-resolution photoelectron spectroscopy in the temperature range 120-620 K, in combination with density functional theory calculations and sum frequency generation spectroscopy. The bare (100) surface exhibits a (3,0; 1,1) reconstruction but restructures during the adsorption process into a Cu-dimer geometry stabilized by methoxy and hydrogen binding in Cu-bridge sites. During the restructuring process, oxygen atoms from the bulk that can host hydrogen appear on the surface. Heating transforms methoxy to formaldehyde, but further dehydrogenation is limited by the stability of the surface and the limited access to surface oxygen. The ( √3 x√ 3)R30°-reconstructed (111) surface is based on ordered surface oxygen and copper ions and vacancies, which offers a palette of adsorption and reaction sites. Already at 140 K, a mixed layer of methoxy, formaldehyde and CHxOy is formed. Heating to room temperature leaves OCH and CHx. Thus both CH-bond breaking and COscission are active on this surface at low temperature. The higher ability to dehydrogenate methanol on (111) compared to (100) is explained by the multitude of adsorption sites and in particular, the availability of surface oxygen. Published by AIP Publishing. [ABSTRACT FROM AUTHOR]

Published

2017