Your search keyword '"Marks, Kess"' showing total 5 results

1. 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, Gothelid, Mats, Harding, Dan J., Ostrom, Henrik, 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, Gothelid, Mats, Harding, Dan J., and Ostrom, Henrik

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 H-2 gas, as well as the formation of carbidic and graphitic surface carbon. Published under license by AIP Publishing.

Published

2019

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, Gothelid, Mats, Harding, Dan J., Ostrom, Henrik, 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, Gothelid, Mats, Harding, Dan J., and Ostrom, Henrik

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 H-2 gas, as well as the formation of carbidic and graphitic surface carbon. Published under license by AIP Publishing.

Published

2019

3. 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, Gothelid, Mats, Harding, Dan J., Ostrom, Henrik, 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, Gothelid, Mats, Harding, Dan J., and Ostrom, Henrik

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 H-2 gas, as well as the formation of carbidic and graphitic surface carbon. Published under license by AIP Publishing.

Published

2019

4. 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, Gothelid, Mats, Harding, Dan J., Ostrom, Henrik, 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, Gothelid, Mats, Harding, Dan J., and Ostrom, Henrik

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 H-2 gas, as well as the formation of carbidic and graphitic surface carbon. Published under license by AIP Publishing.

Published

2019

5. 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, Gothelid, Mats, Harding, Dan J., Ostrom, Henrik, 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, Gothelid, Mats, Harding, Dan J., and Ostrom, Henrik

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 H-2 gas, as well as the formation of carbidic and graphitic surface carbon. Published under license by AIP Publishing.

Published

2019