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A molecular beam-surface apparatus for quantum state-resolved adsorption studies

Understanding the microscopic mechanism of molecule–surface interaction is of great importance in the study of chemical dynamics. Yet, it remains challenging to experimentally acquire quantum state resolved results, particularly the results related to different degrees of freedom of the reactants. H...

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Published in:Review of scientific instruments 2022-01, Vol.93 (1), p.013201-013201
Main Authors: Shen, Qiqi, Wu, Jiawei, Zhou, Feiyue, Song, Yunlong, Dong, Wenrui, Wang, Xingan, Wang, Tao, Yang, Xueming
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container_title Review of scientific instruments
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creator Shen, Qiqi
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Dong, Wenrui
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Wang, Tao
Yang, Xueming
description Understanding the microscopic mechanism of molecule–surface interaction is of great importance in the study of chemical dynamics. Yet, it remains challenging to experimentally acquire quantum state resolved results, particularly the results related to different degrees of freedom of the reactants. Here, we report the design and performance of a new apparatus for molecule–surface dynamics studies, which enable the measurement of quantum state-resolved adsorption. A continuous narrow-linewidth infrared laser source and molecular beam unit were developed and employed in this new apparatus to achieve independent control on different degrees of freedom (translation, vibration, and rotation) of the molecule. Preliminary results on hydrogen and hydrogen chloride adsorption on the Cu (111) surface were also presented.
doi_str_mv 10.1063/5.0049178
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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP - American Institute of Physics
subjects Adsorption
Degrees of freedom
Hydrogen chloride
Infrared lasers
Molecular beams
Scientific apparatus & instruments
Surface chemistry
Surface dynamics
title A molecular beam-surface apparatus for quantum state-resolved adsorption studies
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