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Two year postdoc position at Aarhus University for single molecule FRET based investigations of l...
fluorescent convertase and substrate. A second part of the project will investigate very recently discovered dynamic properties of the complex between the 150 kDa complement receptor 3 (CR3) and its ligands
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experience in all these areas is not required, candidates should demonstrate their capacity to undertake quantitative and computational research to address questions about epidemiological dynamics. A knowledge
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of cementitious materials. Experience with X-ray or neutron tomography. Flexibility is essential. We are looking for a team player who can also work independently, who is motivated to help and be part of a dynamic
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collaborative, cross-cultural research environments. Who we are You will be based at the Department of Electrical and Computer Engineering (ECE) at Aarhus University, a dynamic and growing department committed
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supportive, dynamic and ambitious research environment with a strong scientific and social network for postdoctoral fellows and good mentoring opportunities. Furthermore, you will have access to state
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biological problems and is thus not focused on development of computational methods. We wish to generate small protein binders against a range of important neuroscience targets – principally intrinsically
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deliverables, assisting with project reporting, and facilitating communication across the project consortium. What we offer We offer a dynamic and supportive research environment within an internationally
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August 2025 or as soon as possible thereafter. Job description You will be part of an international and dynamic team to focus on modelling hypo-O-GlcNAcylation in Drosophila, searching for physiological
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. Responsibilities and qualifications You will be part of a dynamic work environment with a pleasant team atmosphere, where you will have the opportunity to grow and develop your academic, industrial, and personal
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- MERFISH) to map single-cell gene expression dynamics spatially and temporally, elucidating disease mechanisms at unprecedented resolution. Investigate the impact of mechanical forces and UV radiation