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Autori principali: Shi, Lei, Schröder, Markus, Meyer, Hans-Dieter, Pelaez, Daniel, Wodtke, Alec M., Golibrzuch, Kai, Schönemann, Anna-Maria, Kandratsenka, Alexander, Gatti, Fabien
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.07246
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author Shi, Lei
Schröder, Markus
Meyer, Hans-Dieter
Pelaez, Daniel
Wodtke, Alec M.
Golibrzuch, Kai
Schönemann, Anna-Maria
Kandratsenka, Alexander
Gatti, Fabien
author_facet Shi, Lei
Schröder, Markus
Meyer, Hans-Dieter
Pelaez, Daniel
Wodtke, Alec M.
Golibrzuch, Kai
Schönemann, Anna-Maria
Kandratsenka, Alexander
Gatti, Fabien
contents This study deals with the understanding of hydrogen atom scattering from graphene, a process critical for exploring C-H bond formation and energy transfer during the atom surface collision. In our previous work (J.Chem.Phys \textbf{159}, 194102, (2023)), starting from a cell with 24 carbon atoms treated periodically, we have achieved quantum dynamics (QD) simulations with a reduced-dimensional model (15D) and a simulation in full dimensionality (75D). In the former work, the H atom attacked the top of a single C atom, enabling a comparison of QD simulation results with classical molecular dynamics (cMD). Our approach required the use of sophisticated techniques such as Monte Carlo Canonical Polyadic Decomposition (MCCPD) and Multilayer Multi-Configuration Time-Dependent Hartree (ML-MCTDH), as well as a further development of quantum flux calculations. We could benchmark our calculations by comparison with cMD calculations. We have now refined our method to better mimic experimental conditions. Specifically, rather than sending the H atom to a specific position on the surface, we have employed a plane wave for the H atom in directions parallel to the surface. Key findings for these new simulations include the identification of discrepancies between classical molecular dynamics (cMD) simulations and experiments, which are attributed to both the potential energy surface (PES) and quantum effects. Additionally, the study sheds light on the role of classical collective normal modes during collisions, providing insights into energy transfer processes. The results validate the robustness of our simulation methodologies and highlight the importance of considering quantum mechanical effects in the study of hydrogen-graphene interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07246
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Full Quantum dynamics study for H atom scattering from graphene
Shi, Lei
Schröder, Markus
Meyer, Hans-Dieter
Pelaez, Daniel
Wodtke, Alec M.
Golibrzuch, Kai
Schönemann, Anna-Maria
Kandratsenka, Alexander
Gatti, Fabien
Chemical Physics
This study deals with the understanding of hydrogen atom scattering from graphene, a process critical for exploring C-H bond formation and energy transfer during the atom surface collision. In our previous work (J.Chem.Phys \textbf{159}, 194102, (2023)), starting from a cell with 24 carbon atoms treated periodically, we have achieved quantum dynamics (QD) simulations with a reduced-dimensional model (15D) and a simulation in full dimensionality (75D). In the former work, the H atom attacked the top of a single C atom, enabling a comparison of QD simulation results with classical molecular dynamics (cMD). Our approach required the use of sophisticated techniques such as Monte Carlo Canonical Polyadic Decomposition (MCCPD) and Multilayer Multi-Configuration Time-Dependent Hartree (ML-MCTDH), as well as a further development of quantum flux calculations. We could benchmark our calculations by comparison with cMD calculations. We have now refined our method to better mimic experimental conditions. Specifically, rather than sending the H atom to a specific position on the surface, we have employed a plane wave for the H atom in directions parallel to the surface. Key findings for these new simulations include the identification of discrepancies between classical molecular dynamics (cMD) simulations and experiments, which are attributed to both the potential energy surface (PES) and quantum effects. Additionally, the study sheds light on the role of classical collective normal modes during collisions, providing insights into energy transfer processes. The results validate the robustness of our simulation methodologies and highlight the importance of considering quantum mechanical effects in the study of hydrogen-graphene interactions.
title Full Quantum dynamics study for H atom scattering from graphene
topic Chemical Physics
url https://arxiv.org/abs/2410.07246