The use of anomalous x-ray diffraction as a tool for the analysis of compound semiconductors

Többens, Daniel M.; Schorr, Susan

doi:10.1088/1361-6641/aa8708

Cited by 5 publications

(1 citation statement)

References 69 publications

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“…For instance, the method was applied for the determination of composition profiles in SiGe nano-islands (Schü lli et al, 2003;Magalhã es-Paniago et al, 2002;Malachias et al, 2003); it was also employed for studying various types of nanoparticles, such as CuInSi 2 in photovoltaic absorber materials (Connor et al, 2013), Pt and PtRu (Jeng et al, 2007) or PtCu nanoparticles (Strasser et al, 2010). Other materials studied by this approach include Heusler alloys (Ravel et al, 2002;Collins et al, 2007), semiconductors (Tö bbens & Schorr, 2017) and long-range ordering in ordered ternary alloys (Marty et al, 1990) and thin films (Maret et al, 2012). AXRD was also employed to identify phases in FeNi-based magnets (Sharma et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Anomalous X-ray diffraction from ω nanoparticles in β-Ti(Mo) single crystals

et al. 2019

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Anomalous X-ray diffraction (AXRD) is a technique which makes use of effects occurring near the energy of an absorption edge of an element present in the studied sample. The intensity of the diffracted radiation exhibits an anomalous decrease when the primary beam energy matches the energy needed to excite an electron from an atomic orbital. The characteristics of this step are sensitive to the concentration of the 'anomalous' element and its spatial distribution in the sample. In the present investigation, AXRD was employed to study ! particles in a metastable titanium alloy Ti-15Mo (in wt%). The experiments were done in an energy range around the Mo K edge at 20.0 keV, allowing investigation of the distribution of Mo in the material, which is rejected from the volume of ! particles during their diffusion-driven growth. This paper deals with diffuse scattering patterns around the (006) diffraction maximum. It was observed that different regions of the diffuse scattering exhibited different variations of diffracted intensity with the incident photon energy near the absorption edge. Numerical simulations of diffuse scattering patterns as well as of energy dependences of the scattered intensity were performed. It was found that the observed patterns and their dependence on the primary beam energy can be explained by taking into account (a) elastic deformation of the matrix arising from the presence of slightly misfitting ! particles and (b) the presence of a 'cloud' of a higher Mo concentration around ! particles.

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Section: Introductionmentioning

confidence: 99%