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and pilot-scale testing of renewable energy technologies. Co-operation with other institutes, companies and universities both in Denmark and internationally is an integrated part of our culture. What we
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to develop high-throughput compatible robotic-assisted functional assays to capture microbial strains' functional performance. Secondly, your in-depth research focus will be on uncovering the activity and fate
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understanding of fundamental principles behind brain functioning in general. With a strong foundation in music practice and theory at the highest level and a focus on the clinical application of music, MIB
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performance metrics such as absorption and diffraction across a large design and material space. Curate and format large datasets of simulated nanostructures and their optical properties in close collaboration
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. Evaluate optical performance metrics such as absorption and diffraction across a large design and material space. Curate and format large datasets of simulated nanostructures and their optical properties in
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well as contributing to other research and advisory activities in our research group. You’ll work hands-on with high-end GC-MS instrumentation (and other analytical equipment) and collaborate closely with researchers
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of hypothesis-generating screening studies, a methodological portfolio where we identify signals of interest from real-world register data to guide the conduct of tailored studies. We have performed such studies
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drive. In particular, we are looking for academic excellence and/or demonstrated scientific achievements. We also expect you to have a strong ability to conceive new ideas, construct high-performance
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, e.g., demonstrated by a track-record of high-impact publications Previous work in inverse design / topology optimization We offer DTU is a leading technical university globally recognized
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these nanocomposites, we are looking for a postdoc to further develop high performance computing numerical methods in our state-of-the-art open source micromagnetic model, MagTense. MagTense is based on a core