Your search keyword '"Liebetrau, Martin"' showing total 5 results

1. Hydrogen Atom Scattering at the Al$_2$O$_3$(0001) Surface: A Combined Experimental and Theoretical Study

Author

Liebetrau, Martin, Dorenkamp, Yvonne, Bünermann, Oliver, and Behler, Jörg

Subjects

Physics - Chemical Physics, Physics - Computational Physics

Abstract

Investigating atom-surface interactions is the key to an in-depth understanding of chemical processes at interfaces, which are of central importance in many fields -- from heterogeneous catalysis to corrosion. In this work, we present a joint experimental and theoretical effort to gain insights into the atomistic details of hydrogen atom scattering at the $\alpha$-Al$_2$O$_3$(0001) surface. Surprisingly, this system has been hardly studied to date, although hydrogen atoms as well as $\alpha$-Al$_2$O$_3$ are omnipresent in catalysis as reactive species and support oxide, respectively. We address this system by performing hydrogen atom beam scattering experiments and molecular dynamics (MD) simulations based on a high-dimensional machine learning potential trained to density functional theory data. Using this combination of methods we are able to probe the properties of the multidimensional potential energy surface governing the scattering process. Specifically, we compare the angular distribution and the kinetic energy loss of the scattered atoms obtained in experiment with a large number of MD trajectories, which, moreover, allow to identify the underlying impact sites at the surface., Comment: 13 pages, 8 figures

Published

2023

2. Hydrogen atom scattering at the Al2O3(0001) surface: a combined experimental and theoretical study

Author

Liebetrau, Martin, primary, Dorenkamp, Yvonne, additional, Bünermann, Oliver, additional, and Behler, Jörg, additional

Published

2024

3. Hydrogen atom scattering at the Al2O3(0001) surface: a combined experimental and theoretical study.

Author

Liebetrau, Martin, Dorenkamp, Yvonne, Bünermann, Oliver, and Behler, Jörg

Abstract

Investigating atom–surface interactions is the key to an in-depth understanding of chemical processes at interfaces, which are of central importance in many fields – from heterogeneous catalysis to corrosion. In this work, we present a joint experimental and theoretical effort to gain insights into the atomistic details of hydrogen atom scattering at the α-Al2O3(0001) surface. Surprisingly, this system has been hardly studied to date, although hydrogen atoms as well as α-Al2O3 are omnipresent in catalysis as reactive species and support oxide, respectively. We address this system by performing hydrogen atom beam scattering experiments and molecular dynamics (MD) simulations based on a high-dimensional machine learning potential trained to density functional theory data. Using this combination of methods we are able to probe the properties of the multidimensional potential energy surface governing the scattering process. Specifically, we compare the angular distribution and the kinetic energy loss of the scattered atoms obtained in experiment with a large number of MD trajectories, which, moreover, allow to identify the underlying impact sites at the surface. [ABSTRACT FROM AUTHOR]

Published

2024

4. Sinusthrombose

Author

Mäurer, Mathias, Hamann, Gerhard F., Liebetrau, Martin, Schwab, Stefan, editor, Schellinger, Peter, editor, Werner, Christian, editor, Unterberg, Andreas, editor, and Hacke, Werner, editor

Published

2015

5. Hydrogen atom scattering at the Al 2 O 3 (0001) surface: a combined experimental and theoretical study.

Author

Liebetrau M, Dorenkamp Y, Bünermann O, and Behler J

Abstract

Investigating atom-surface interactions is the key to an in-depth understanding of chemical processes at interfaces, which are of central importance in many fields - from heterogeneous catalysis to corrosion. In this work, we present a joint experimental and theoretical effort to gain insights into the atomistic details of hydrogen atom scattering at the α-Al 2 O 3 (0001) surface. Surprisingly, this system has been hardly studied to date, although hydrogen atoms as well as α-Al 2 O 3 are omnipresent in catalysis as reactive species and support oxide, respectively. We address this system by performing hydrogen atom beam scattering experiments and molecular dynamics (MD) simulations based on a high-dimensional machine learning potential trained to density functional theory data. Using this combination of methods we are able to probe the properties of the multidimensional potential energy surface governing the scattering process. Specifically, we compare the angular distribution and the kinetic energy loss of the scattered atoms obtained in experiment with a large number of MD trajectories, which, moreover, allow to identify the underlying impact sites at the surface.

Published

2024