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Main Authors: Specht, Petra, Kang, Joo H., Tarafder, Kartick, Cieslinski, Robert, Barton, David, Barton, Bastian, Carlsson, Anna, Wang, Lin-Wang, Kisielowski, Christian
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.05689
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author Specht, Petra
Kang, Joo H.
Tarafder, Kartick
Cieslinski, Robert
Barton, David
Barton, Bastian
Carlsson, Anna
Wang, Lin-Wang
Kisielowski, Christian
author_facet Specht, Petra
Kang, Joo H.
Tarafder, Kartick
Cieslinski, Robert
Barton, David
Barton, Bastian
Carlsson, Anna
Wang, Lin-Wang
Kisielowski, Christian
contents The static and genuine structure of small rhodium and rhodium/tungsten nanoparticles on an alumina support can be imaged with atomic resolution even if single digit atom clusters are investigated. Low dose rate electron microscopy is key to the achievement and can generally be applied to investigate any similar material. In such conditions it becomes feasible to identify the chemical composition of nanocrystals from quantitative contrast analyses alone by counting atoms. The ability to fully characterize an unaltered, initial state of the objects allows targeting structural excitations or conformational changes induced by the electron beam itself. For the specific case of catalytic Rh:W particles we stimulate a tungsten-promoted size regulation mechanism in real time that is driven by Oswald ripening and can be understood by a strong binding of tungsten atoms to the oxygen atoms of the support, which builds up strain as the cluster sizes increase.
format Preprint
id arxiv_https___arxiv_org_abs_2406_05689
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Realtime observation of a tungsten-promoted size regulation mechanism in a rhodium catalyst at atomic resolution
Specht, Petra
Kang, Joo H.
Tarafder, Kartick
Cieslinski, Robert
Barton, David
Barton, Bastian
Carlsson, Anna
Wang, Lin-Wang
Kisielowski, Christian
Materials Science
The static and genuine structure of small rhodium and rhodium/tungsten nanoparticles on an alumina support can be imaged with atomic resolution even if single digit atom clusters are investigated. Low dose rate electron microscopy is key to the achievement and can generally be applied to investigate any similar material. In such conditions it becomes feasible to identify the chemical composition of nanocrystals from quantitative contrast analyses alone by counting atoms. The ability to fully characterize an unaltered, initial state of the objects allows targeting structural excitations or conformational changes induced by the electron beam itself. For the specific case of catalytic Rh:W particles we stimulate a tungsten-promoted size regulation mechanism in real time that is driven by Oswald ripening and can be understood by a strong binding of tungsten atoms to the oxygen atoms of the support, which builds up strain as the cluster sizes increase.
title Realtime observation of a tungsten-promoted size regulation mechanism in a rhodium catalyst at atomic resolution
topic Materials Science
url https://arxiv.org/abs/2406.05689