Core level photoemission line shape selection: Atomic adsorbates on iron

Core level photoemission line shape selection: Atomic adsorbates on iron

Robust fitting of core level photoemission spectra is often central to reliable interpretation of X‐ray photoelectron spectroscopy (XPS) data. One key element is employment of the correct line shape function for each spectral component. In this study, we consider this topic, focusing on XPS data fro...

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Bibliographic Details
Published in:Surface and interface analysis Vol. 52; no. 8; pp. 507 - 512
Main Authors: Acres, Matthew J., Hussain, Hadeel, Walczak, Monika S., Nikiel, Marek, Sewell, Christopher, Rafols i Belles, Carles, Ahmad, Ehsan A., Walton, Alexander S., Muryn, Christopher A., Harrison, Nicholas M., Lindsay, Robert
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-08-2020
Subjects:
ab initio modelling
Adsorbates
Asymmetry
atomic adsorbate
Data acquisition
Density functional theory
Fermi level
Iron
Line shape
oxygen
Photoelectric emission
Photoelectrons
Photoexcitation
Shape functions
Spectra
Spectrum analysis
sulfur
XPS
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Summary:Robust fitting of core level photoemission spectra is often central to reliable interpretation of X‐ray photoelectron spectroscopy (XPS) data. One key element is employment of the correct line shape function for each spectral component. In this study, we consider this topic, focusing on XPS data from atomic adsorbates, namely, O and S, on Fe(110). The potential of employing density functional theory (DFT) for generating adsorbate projected electronic density of states (PDOS) to support line shape selection is explored. O 1s core level XPS spectra, acquired from various ordered overlayers of chemisorbed O, all display an equivalent asymmetric line shape. Previous work suggests that this asymmetry is a result of finite O PDOS in the vicinity of the Fermi level, allowing O 1s photoexcitation to induce a weighted continuum of final states through electron‐hole pair excitation. This origin is corroborated by O DFT‐PDOS generated for an optimised five‐layer Fe(110)(2 × 2)‐O slab. Adsorbate DFT‐PDOS were also computed for Fe(110) 2112 ‐S. As, similar to adsorbed O, there is a significant continuous distribution of states about the Fermi level, it is proposed that the S 2p XPS core levels should also have asymmetric profiles. S 2p XPS data acquired from Fe(110) 2112 ‐S, and their subsequent fitting, verify this prediction, suggesting that DFT‐PDOS could aid line shape selection.
ISSN:0142-2421
1096-9918
DOI:10.1002/sia.6770