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supportive scientific environment. As a PhD student in this project, you will: Conduct quantum sensing experiments at cryogenic temperatures Investigate the photophysics and spin dynamics of NV and SiV centers
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& Competencies: Familiarity with computational fluid dynamics and ability to design mechanical and microfluidic components Strong expertise in cell culture and molecular biology techniques Experience in
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starting of 1st of December, 2025. We are providing a supportive environment that fosters professional and personal growth . You will join a dynamic, motivated and interdisciplinary team of researchers with
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importance, the precise molecular mechanisms by which Hsp90 recognizes, processes, and releases its client proteins remain elusive due to the complex and dynamic nature of these processes. This doctoral
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environment with a dynamic and international group of researchers. Our team has a strong track record of publishing in leading journals such as Academy of Management Journal, Management Science, Organization
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fluency is not needed but considered a plus. You are a dynamic and curious person, highly motivated to work to face environmental challenges, in multidisciplinary and international collaborations. Our offer
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-world energy applications, the project aims to better capture the dynamics of urban infrastructures across different spatial and temporal scales, from building-level energy demand to district-scale
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Your position Biomolecular dynamics, such as conformational changes, are the understudied link between biomolecular structure and function. Single-molecule FRET is an established technique, unique
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enables label-free trapping and sensing of single proteins in solution for up to hours. Now, we leverage the unique abilities of nanopore trapping to detect proteins and their conformations, dynamics
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continuum modeling (finite element modeling, computational fluid dynamics), and proven experience with COMSOL Multiphysics. Knowledge of heat and mass transport processes in heat-sensitive materials and