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generation and laser-induced electron diffraction. In particular, we aim to translate the seminal concepts of strong-field physics towards the weak-field regime for the first time. This achievement would
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crystalline materials with interesting magnetic and electronic ground states. Here, a special focus lies on crystal growth through chemical transport reactions and flux methods as well as X-ray diffraction
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the fields of nanoelectrochemistry, electrochemical imaging, kinetics and mechanisms, hydrodynamic techniques, spectroscopy, microscopy (AFM and STEM), programming, data analysis, and multiphysics modelling
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nanoscale X-ray diffraction (XRD) methods to image domain dynamics in ferroelectric materials. These are characterized by the existence of domains in which there is an aligned polarization, similar
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laser/X-ray spectroscopy. Novel methods for characterizing, accessing, and manipulating amorphous materials and biological materials. Coherent diffraction imaging and its applications in free electron
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Coherent Diffraction Imaging (BCDI), ptychography, and X-ray Photon Correlation Spectroscopy (XPCS). The goal is to move beyond simple correlations to discover the causal, governing rules of defect-property
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of experts in material synthesis, electrical characterization, device simulations, high-resolution imaging and synchrotron research. The division has own laboratories in the Ångström clean-room lab
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limitations in terms of accuracy, speed, and adaptability across various use cases. This project aims to develop a compact, scalable, and cost-effective microscope system based on coherent diffractive imaging
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-correction, electron energy loss spectroscopy, energy dispersive X-ray spectroscopy, selected area electron diffraction, convergent beam electron diffraction, 4D-STEM, and energy filtered imaging. Experience
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& catalysis, life sciences and magnetism. The second branch has a stronger focus on exploring coherence, with diffraction imaging, holography and x-ray photon correlation spectroscopy (XPCS). The SoftiMAX team