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of Operating Microelectronic Devices by X-ray Diffraction Microscopy Beamline ID01, at the ESRF is a world leading instrument dedicated to micro- and nano-beam X-ray diffraction imaging experiments. It enables
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University Bochum Project 2: “In situ studies of the mechanochemical synthesis of intermetallic compounds” under the supervision of Prof. Weidenthaler, Powder Diffraction and Surface Spectroscopy group
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the form of coatings, ablation and high-heat-flux testing rigs, and characterisation using secondary electron imaging, X-ray diffractometry, electron backscattered diffraction, transmission electron
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synchrotron method: 2DµXRD imaging. We have recently demonstrated a proof of concept of this experiment4. The PhD aims at (a) increasing resolution of 2DµXRD imaging and (b) make this technique available
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. This PhD project will focus on the design and development of UHT ceramics in the form of coatings, ablation and high-heat-flux testing rigs, and characterisation using secondary electron imaging, X-ray
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I supervise computational projects in electron microscopy imaging for investigating materials at atomic resolution. Some projects centre on analysing experimental data acquired by experimental
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inside hadrons, and the emergence of gluon saturation at high energies. A central goal of the project is to build a three-dimensional picture of hadron structure, encoding both the longitudinal momentum
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of mineralogical characterization of materials (pictorial and others) to the understanding of rock surfaces. The use of hyperspectral imaging, which is non-invasive and non-destructive, is central to current
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limit of spatial resolution devise computational strategies to ensure diffraction-limited performance dive into hybrid computational/traditional imaging systems and optical design push measurement
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an HHG source of ultrashort XUV pulses as the primary light source. The MAC user end-station is equipped with electron/ion spectrometers, detectors for coherent diffractive imaging and state-of-the-art