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crystallographic studies 2. Collect NMR data on labeled proteins for structural and biophysical studies 3. Screen proteins for crystallization and diffraction 4. Determine protein structures using X-ray diffraction
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growth (PLD, MBE, and CVD methods), crystal, and interface structure determination with x-ray diffraction/scattering/spectroscopy, transport and magnetic property characterization using Quantum Design’s
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will have strong links to the experimental synthesis, diffraction and electrochemical work performed in the overall project. Previous experience in computer modelling of lithium battery cathodes and a
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(e.g., coherent diffraction imaging, X-ray reflectivity) or the use of scanning probe and/or optical microscopy Considerable knowledge of interfacial chemistry or materials science; experimental
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with e.g. powder diffraction Experience with wet chemical synthesis, e.g. nanoparticles A distinct advantage would be: Experience with high-level programming languages, e.g. Python Knowledge in magnetism
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coefficient modeling. Experience in integrating modeling with leaching and separation processes for scale-up. Advanced data interpretation using electron diffraction, dendritic growth modeling, and REE behavior
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. This project uses crystal growth and physical property measurements to develop, understand, and control new and emerging materials. This position resides in the Correlated Electron Materials Group in
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imaging methods complemented by in house X-ray imaging (axia.au.dk). Additionally, X-ray fluorescence, scattering, diffraction-based imaging will be employed. The biological and bioinspired materials group
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imaging methods complemented by in house X-ray imaging (axia.au.dk). Additionally, X-ray fluorescence, scattering, diffraction-based imaging will be employed. The biological and bioinspired materials group
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-ray synchrotrons and the Linear Coherent Light Source’s X-ray free electron laser to access world-class capabilities for Resonant Inelastic X-ray Scattering (RIXS). A major goal of the eXn group is to