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groundbreaking electron-beam lithography (EBL) methods that will redefine what is achievable in quantum device fabrication. You will push lithography resolution limits down to the quantum regime, demonstrating
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experimental research in nanoparticle catalysis using advanced operando electron microscopy This collaborative PhD project between Technical University of Munich (TUM) ( the group of Prof. Barbara A.J. Lechner
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, fluorescence spectroscopy, calorimetry, electron microscopy; lipids extraction and characterisation using mass spectrometry; cell culture (established and iPS cell lines), Immunocytochemistry, Western Blot, qPCR
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that model the complex space of ingredients and their properties can be immensely useful. These representation spaces can be informed by multiple modalities of data, spanning time-series data, microscopy
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groundbreaking electron-beam lithography (EBL) methods that will redefine what is achievable in quantum device fabrication. You will push lithography resolution limits down to the quantum regime, demonstrating
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electron-beam lithography (EBL) methods that will redefine what is achievable in quantum device fabrication. You will push lithography resolution limits down to the quantum regime, demonstrating
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measurements and proteomics), and microscopy (AFM, confocal and fluorescence) instruments, microscope with cold stage, rate freezer and climate cabinets, GMO class 2 labs, flow cytometry, NGS, Q-PCR facilities
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properties of the electrodes will enhance interaction with bacteria and facilitate electron transfer. Here, we will focus on design and fabrication of 3D carbon electrodes, which can provide excellent
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electron microscopy (TEM), and X-ray photoelectron spectroscopy (XPS) You must have a two-year master's degree (120 ECTS points) or a similar degree with an academic level equivalent to a two-year master's