4.8 Article

Quantitative Element-Sensitive Analysis of Individual Nanoobjects

Journal

SMALL
Volume 19, Issue 9, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/smll.202204943

Keywords

nanobeam X-ray fluorescence (XRF); nanometrology; nanostructure characterization; quantitative analysis

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A reliable and quantitative material analysis is important for understanding advanced material properties at the nanoscale. X-ray fluorescence microscopy can provide an element-sensitive and non-destructive tool for investigating nanotechnological materials. However, the quantification capabilities of these approaches are often limited. This study demonstrates that a traceable quantification of individual nanoobjects can be achieved using an X-ray fluorescence microscope with well-calibrated instrumentation instead of reference materials.
A reliable and quantitative material analysis is crucial for assessing new technological processes, especially to facilitate a quantitative understanding of advanced material properties at the nanoscale. To this end, X-ray fluorescence microscopy techniques can offer an element-sensitive and non-destructive tool for the investigation of a wide range of nanotechnological materials. Since X-ray radiation provides information depths of up to the microscale, even stratified or buried arrangements are easily accessible without invasive sample preparation. However, in terms of the quantification capabilities, these approaches are usually restricted to a qualitative or semi-quantitative analysis at the nanoscale. Relying on comparable reference nanomaterials is often not straightforward or impossible because the development of innovative nanomaterials has proven to be more fast-paced than any development process for appropriate reference materials. The present work corroborates that a traceable quantification of individual nanoobjects can be realized by means of an X-ray fluorescence microscope when utilizing rather conventional but well-calibrated instrumentation instead of reference materials. As a proof of concept, the total number of atoms forming a germanium nanoobject is quantified using soft X-ray radiation. Furthermore, complementary dimensional parameters of such objects are reconstructed.

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