Electrostatic potentials of atomic nanostructures at metal surfaces quantified by scanning quantum dot microscopy

Rustem Bolat; Jose M. Guevara; Philipp Leinen; Marvin Knol; Hadi H. Arefi; Michael Maiworm; Rolf Findeisen; Ruslan Temirov; Oliver T. Hofmann; Reinhard J. Maurer; F. Stefan Tautz; Christian Wagner

doi:10.1038/s41467-024-46423-4

Electrostatic potentials of atomic nanostructures at metal surfaces quantified by scanning quantum dot microscopy

Rustem Bolat, Jose M. Guevara, Philipp Leinen, Marvin Knol, Hadi H. Arefi, Michael Maiworm, Rolf Findeisen, Ruslan Temirov, Oliver T. Hofmann, Reinhard J. Maurer, F. Stefan Tautz, Christian Wagner^*

^*Corresponding author for this work

Institute of Solid State Physics (5130)

Research output: Contribution to journal › Article › peer-review

Abstract

The discrete and charge-separated nature of matter — electrons and nuclei — results in local electrostatic fields that are ubiquitous in nanoscale structures and relevant in catalysis, nanoelectronics and quantum nanoscience. Surface-averaging techniques provide only limited experimental access to these potentials, which are determined by the shape, material, and environment of the nanostructure. Here, we image the potential over adatoms, chains, and clusters of Ag and Au atoms assembled on Ag(111) and quantify their surface dipole moments. By focusing on the total charge density, these data establish a benchmark for theory. Our density functional theory calculations show a very good agreement with experiment and allow a deeper analysis of the dipole formation mechanisms, their dependence on fundamental atomic properties and on the shape of the nanostructures. We formulate an intuitive picture of the basic mechanisms behind dipole formation, allowing better design choices for future nanoscale systems such as single-atom catalysts.

Original language	English
Article number	2259
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-46423-4
Publication status	Published - Dec 2024

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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Bolat, R., Guevara, J. M., Leinen, P., Knol, M., Arefi, H. H., Maiworm, M., Findeisen, R., Temirov, R., Hofmann, O. T., Maurer, R. J., Tautz, F. S., & Wagner, C. (2024). Electrostatic potentials of atomic nanostructures at metal surfaces quantified by scanning quantum dot microscopy. Nature Communications, 15(1), Article 2259. https://doi.org/10.1038/s41467-024-46423-4

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title = "Electrostatic potentials of atomic nanostructures at metal surfaces quantified by scanning quantum dot microscopy",

abstract = "The discrete and charge-separated nature of matter — electrons and nuclei — results in local electrostatic fields that are ubiquitous in nanoscale structures and relevant in catalysis, nanoelectronics and quantum nanoscience. Surface-averaging techniques provide only limited experimental access to these potentials, which are determined by the shape, material, and environment of the nanostructure. Here, we image the potential over adatoms, chains, and clusters of Ag and Au atoms assembled on Ag(111) and quantify their surface dipole moments. By focusing on the total charge density, these data establish a benchmark for theory. Our density functional theory calculations show a very good agreement with experiment and allow a deeper analysis of the dipole formation mechanisms, their dependence on fundamental atomic properties and on the shape of the nanostructures. We formulate an intuitive picture of the basic mechanisms behind dipole formation, allowing better design choices for future nanoscale systems such as single-atom catalysts.",

author = "Rustem Bolat and Guevara, {Jose M.} and Philipp Leinen and Marvin Knol and Arefi, {Hadi H.} and Michael Maiworm and Rolf Findeisen and Ruslan Temirov and Hofmann, {Oliver T.} and Maurer, {Reinhard J.} and Tautz, {F. Stefan} and Christian Wagner",

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AU - Bolat, Rustem

AU - Guevara, Jose M.

AU - Leinen, Philipp

AU - Knol, Marvin

AU - Arefi, Hadi H.

AU - Maiworm, Michael

AU - Findeisen, Rolf

AU - Temirov, Ruslan

AU - Hofmann, Oliver T.

AU - Maurer, Reinhard J.

AU - Tautz, F. Stefan

AU - Wagner, Christian

PY - 2024/12

Y1 - 2024/12

N2 - The discrete and charge-separated nature of matter — electrons and nuclei — results in local electrostatic fields that are ubiquitous in nanoscale structures and relevant in catalysis, nanoelectronics and quantum nanoscience. Surface-averaging techniques provide only limited experimental access to these potentials, which are determined by the shape, material, and environment of the nanostructure. Here, we image the potential over adatoms, chains, and clusters of Ag and Au atoms assembled on Ag(111) and quantify their surface dipole moments. By focusing on the total charge density, these data establish a benchmark for theory. Our density functional theory calculations show a very good agreement with experiment and allow a deeper analysis of the dipole formation mechanisms, their dependence on fundamental atomic properties and on the shape of the nanostructures. We formulate an intuitive picture of the basic mechanisms behind dipole formation, allowing better design choices for future nanoscale systems such as single-atom catalysts.

AB - The discrete and charge-separated nature of matter — electrons and nuclei — results in local electrostatic fields that are ubiquitous in nanoscale structures and relevant in catalysis, nanoelectronics and quantum nanoscience. Surface-averaging techniques provide only limited experimental access to these potentials, which are determined by the shape, material, and environment of the nanostructure. Here, we image the potential over adatoms, chains, and clusters of Ag and Au atoms assembled on Ag(111) and quantify their surface dipole moments. By focusing on the total charge density, these data establish a benchmark for theory. Our density functional theory calculations show a very good agreement with experiment and allow a deeper analysis of the dipole formation mechanisms, their dependence on fundamental atomic properties and on the shape of the nanostructures. We formulate an intuitive picture of the basic mechanisms behind dipole formation, allowing better design choices for future nanoscale systems such as single-atom catalysts.

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Electrostatic potentials of atomic nanostructures at metal surfaces quantified by scanning quantum dot microscopy

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