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of semiconductor and solar cell physics is required Knowledge of solar cell characterization methods and/or drift-diffusion simulations is useful but not mandatory Our Offer: We work on highly innovative topics and
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, and interfacial reactivity under nanoconfinement is essential for the optimal design of next-generation ECL materials. As a PhD candidate at Theory and Computation of Energy Materials, you will be part
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Your Job: Future battery technologies are urgently needed to make electromobility and home storage even faster and more powerful. In order to increase battery performance and energy density at cell
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Your Job: In a project with a leading German aircraft turbine manufacturer, the Institute of Energy and Climate Research - Materials Microstructure and Properties (IEK-2), investigates deposit
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electromobility and home storage even faster and more powerful. In order to increase battery performance and energy density at cell level, electrode materials are to be specifically optimized for high-performance
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(large scale genomic, transcriptomic, proteomic, metabolomic and/or single cell data) using cutting-edge technologies e.g. Artificial Intelligence (AI) Development of novel tools and algorithms in the area
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, the Institute of Energy and Climate Research - Materials Microstructure and Properties (IEK-2), investigates deposit-induced corrosion of turbine blade Ni-base alloys and coatings. Your research work will be
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the highest possible performance in the different cell designs and thus demonstrate the industrial relevance Characterization of the materials, cells and, if necessary, degradation phenomena using advanced
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degree in biophysics, biochemistry, molecular or cell biology or related field. Applications from Physics masters are particularly encouraged. Strong experimental skills in biophysics, molecular cell