AI Article Synopsis
- Artifacts like the Si escape peak and absorption edges can mislead microanalysts into thinking trace elements are present in samples, complicating electron-excited energy dispersive X-ray spectrometry.
- A newly identified artifact related to Compton scattering occurs under specific circumstances with a low atomic number matrix and may have gone unnoticed due to its small signal size.
- With advances in silicon drift detectors, more analysts might encounter this artifact, potentially misidentifying it as a significant presence of a non-existent element.
Article Abstract
Artifacts are the nemesis of trace element analysis in electron-excited energy dispersive X-ray spectrometry. Peaks that result from nonideal behavior in the detector or sample can fool even an experienced microanalyst into believing that they have trace amounts of an element that is not present. Many artifacts, such as the Si escape peak, absorption edges, and coincidence peaks, can be traced to the detector. Others, such as secondary fluorescence peaks and scatter peaks, can be traced to the sample. We have identified a new sample-dependent artifact that we attribute to Compton scattering of energetic X-rays generated in a small feature and subsequently scattered from a low atomic number matrix. It seems likely that this artifact has not previously been reported because it only occurs under specific conditions and represents a relatively small signal. However, with the advent of silicon drift detectors and their utility for trace element analysis, we anticipate that more people will observe it and possibly misidentify it. Though small, the artifact is not inconsequential. Under some conditions, it is possible to mistakenly identify the Compton scatter artifact as approximately 1% of an element that is not present.
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| http://dx.doi.org/10.1017/S1431927611012189 | DOI Listing |
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