AI Article Synopsis
- * By employing a crystalline substrate and an oblique scattering setup, the study minimizes interference from substrate scattering, allowing clearer data collection from the film itself.
- * A combination of advanced detectors, energy filtering, and strategic sample design helps reduce background noise and improve measurement accuracy, with theoretical simulations aiding in understanding X-ray interactions within the materials.
Article Abstract
This article demonstrates the feasibility of obtaining accurate pair distribution functions of thin amorphous films down to 80 nm, using modern laboratory-based X-ray sources. The pair distribution functions are obtained using a single diffraction scan without the requirement of additional scans of the substrate or of the air. By using a crystalline substrate combined with an oblique scattering geometry, most of the Bragg scattering of the substrate is avoided, rendering the substrate Compton scattering the primary contribution. By utilizing a discriminating energy filter, available in the latest generation of modern detectors, it is demonstrated that the Compton intensity can further be reduced to negligible levels at higher wavevector values. Scattering from the sample holder and the air is minimized by the systematic selection of pixels in the detector image based on the projected detection footprint of the sample and the use of a 3D-printed sample holder. Finally, X-ray optical effects in the absorption factors and the ratios between the Compton intensity of the substrate and film are taken into account by using a theoretical tool that simulates the electric field inside the film and the substrate, which aids in planning both the sample design and the measurement protocol.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11460393 | PMC |
| http://dx.doi.org/10.1107/S1600576724006368 | DOI Listing |
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