Lammer, J., Berger, C., Löffler, S., Knez, D., Longo, P., Kothleitner, G., Hofer, F., Haberfehlner, G., Bucher, E., Sitte, W., & Grogger, W. (2022). A method for a column-by-column EELS quantification of barium lanthanum ferrate. Ultramicroscopy, 234, Article 113477. https://doi.org/10.1016/j.ultramic.2022.113477
E057-02 - Fachbereich Universitäre Serviceeinrichtung für Transmissions- Elektronenmikroskopie
-
Journal:
Ultramicroscopy
-
ISSN:
0304-3991
-
Date (published):
26-Jan-2022
-
Number of Pages:
9
-
Publisher:
Elsevier
-
Peer reviewed:
Yes
-
Keywords:
Barium lanthanum ferrate; EELS quantification; High-resolution STEM; Inelastic multislice simulations; Second order Ruddlesden-Popper phase
en
Abstract:
High-resolution STEM-EELS provides information about the composition of crystalline materials at the atomic scale, though a reliable quantitative chemical analysis is often hampered by zone axis conditions, where neighbouring atomic column intensities contribute to the signal at the probe position. In this work, we present a procedure to determine the concentration of two elements within equivalent atomic columns from EELS elemental maps - in our case barium and lanthanum within the A-sites of Ba1.1La1.9Fe2O7, a second order Ruddlesden-Popper phase. We took advantage of the large changes in the elemental distribution from column to column and introduced a technique, which substitutes inelastic scattering cross sections during the quantification step by using parameters obtained from the actual experiment. We considered channelling / de-channelling effects via inelastic multislice simulations and were thereby able to count occupancies in each atomic column. The EELS quantification results were then used as prior information during the Rietveld refinement in XRD measurements in order to differentiate between barium and lanthanum.
en
Project (external):
Austrian Research Promotion Agency FFG Klima- und Energiefonds European Union Horizon 2020 Austrian Science Fund (FWF) Zukunftsfonds Steiermark
-
Project ID:
853538 871659 823717–ESTEEM3 I4309-N36 9016
-
Research Areas:
Visual Computing and Human-Centered Technology: 47% Materials Characterization: 38% Quantum Metrology and Precision Measurements: 15%