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scattering, cryo-electron and fluorescence microscopy. The experimental and theoretical methods used often have their origins in physics. Significant work is devoted to protein self-assembly and co-assembly
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using a combination of classical and advanced techniques including optical and NMR spectroscopy, surface plasmon resonance, light and X-ray scattering, cryo-electron and fluorescence microscopy
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-electron microscopy (cryo-EM) and tomography (cryo-ET) are performed. The group values a collegial and supportive research environment, with open communication, structured mentoring, and a strong emphasis on
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and molecular genetics as well as hands-on experience with cloning, live-cell fluorescence microscopy, image analysis, and sample preparation for sequencing and multi-omics analyses. The main model
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facilities such as MAX IV (Lund), SciLifeLab (Stockholm), and CFIM (Copenhagen), where cryo-electron microscopy (cryo-EM) and tomography (cryo-ET) are performed. The group values a collegial and supportive
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of today’s most challenging materials — in particular, advanced battery materials and solid–liquid interfaces. By combining state-of-the-art instruments such as electron microscopy and atom probe
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the highly collaborative and supportive Laboratory of Organic Electronics (https://www.liu.se/loe ). Your work will primarily be under the guidance of Dr. Jennifer Gerasimov, with additional guidance by Prof
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for heterogeneous catalysis of gas and vapor phase reactants. Finally, you will have access to world-class characterization through collaboration with the electron microscopy center at Stockholm University. Your
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, sealed ampoules) at high temperatures Structural and compositional characterization using X-ray diffraction (single crystal and powder incl. Rietveld) and scanning electron microscopy with EDX Initial