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primarily affiliated with the project Collective Applause in the Symphonic Concert Hall (CLAPS) but there is also a possibility for limited teaching activities. The successful applicant will be expected
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. Responsibilities and qualifications Your primary focus will be to develop a comprehensive database and conduct novel research on how university innovation ecosystems influence the performance and scaling of deep
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inflammation, membranes, neuroscience and personalised medicine. The Department of Biomedicine provides research-based teaching of the highest quality and is responsible for a large part of the medical degree
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in complex in-situ environments. The key responsibility of the position is to develop post-processing methods to extra essential features from the collected measurement data despite drone positional
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of Culture and Society. At the School of Culture and Society, the object of research and teaching is the interplay between culture and society in time and space: From the traditional disciplines
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University and Aarhus University Hospital, involving both Health and Science at AU. The overall project will both use an existing clinical cohort, develop the framework for a new cohort and analyse data from
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Postdoc in assessing carbon sequestration potential of different wetlands as nature-based solutio...
the research environment and that you will contribute positively to the social working environment. We also expect that you will take part in our teaching activities and that you will report research results in
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of what makes an effective biofertilizer and to develop the enabling technologies and translational framework needed to bring robust and affordable microbial solutions to farmers across the globe
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tasks will be: Develop and apply electromagnetic modelling techniques in combination with inverse design to study light-matter interactions in dielectric nanostructured optical surfaces. Evaluate optical
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the project. Your main tasks will be: Develop and apply electromagnetic modelling techniques in combination with inverse design to study light-matter interactions in dielectric nanostructured optical surfaces