The CoESCA station at BESSY: Auger electron–photoelectron coincidences from surfaces demonstrated for Ag MNN

In this work, we present the CoESCA station for electron–electron coincidence spectroscopy from surfaces, built in a close collaboration between Uppsala University and Helmholtz-Zentrum Berlin at the BESSY II synchrotron facility in Berlin, Germany. We start with a detailed overview of previous work...

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Published inJournal of electron spectroscopy and related phenomena Vol. 250; p. 147075
Main Authors Leitner, T., Born, A., Bidermane, I., Ovsyannikov, R., Johansson, F.O.L., Sassa, Y., Föhlisch, A., Lindblad, A., Schumann, F.O., Svensson, S., Mårtensson, N.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.07.2021
Subjects
AES
APECS
Auger
Coincidence
PES
Photoelectron
Spectroscopy
Surface science
Photoelectron
Spectroscopy
Coincidence
Surface science
Auger
AES
PES
APECS
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Summary:In this work, we present the CoESCA station for electron–electron coincidence spectroscopy from surfaces, built in a close collaboration between Uppsala University and Helmholtz-Zentrum Berlin at the BESSY II synchrotron facility in Berlin, Germany. We start with a detailed overview of previous work in the field of electron–electron coincidences, before we describe the CoESCA setup and its design parameters. The system is capable of recording shot-to-shot resolved 6D coincidence datasets, i.e. the kinetic energy and the two take off angles for both coincident electrons. The mathematics behind extracting and analysing these multi-dimensional coincidence datasets is introduced, with a focus on coincidence statistics, resulting in fundamental limits of the signal-to-noise ratio and its implications for acquisition times and the size of the raw data stream. The functionality of the CoESCA station is demonstrated for the example of Auger electron–photoelectron coincidences from silver surfaces for photoelectrons from the Ag 3d core levels and their corresponding MNN Auger electrons. The Auger spectra originating from the different core levels, 3d3∕2 and 3d5∕2 could be separated and further, the two-hole state energy distributions were determined for these Auger decay channels. •Auger electron–Photoelectron Coincidence spectroscopy (APECS) from surfaces.•Disentangling Auger decay spectra from Ag 3d core level photoionisation.•New synchrotron end station for user operation at BESSY II.
ISSN:0368-2048
1873-2526
1873-2526
DOI:10.1016/j.elspec.2021.147075