45 postdoctoral-fluid-structure-interaction PhD positions at Technical University of Denmark
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energy systems. From investigating nanoscale structures to macro-scale atmospheric flow; from designing the turbines of tomorrow to the digital energy solutions of the future; from developing electric
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-matter interactions for applications in sensing, optical communications, and quantum technologies. The scientific environment at our department is vibrant and highly collaborative with world-class
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molecular interactions between ICB and γδ T cells. Position 2 will focus on the potential role of γδ T cells in immune related adverse effects (irAEs). Both positions will be in close collaboration with
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, data science, computer science, and computer engineering, including artificial intelligence (AI), machine learning, internet of things (IoT), chip design, cybersecurity, human-computer interaction
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investigating nanoscale structures to macro-scale atmospheric flow; from designing the turbines of tomorrow to the digital energy solutions of the future; from developing electric power systems to exploring more
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project investigates how to better structure, manage, and align early-stage and later-stage financing for university-based deep tech startups. The candidate hired will be expected to explore financing gaps
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, and Altium; has good experience in PCB schematic and layout, and making laboratory prototypes, debugging, and testing power electronic circuits; is target-oriented, structured thinking, eager to learn
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Atmospheric Division, current focus areas cover large-scale structure of the universe, physics of compact objects and transient phenomena, exoplanets, upper atmosphere physics and cosmo-climatology, as
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‘bringing science to life’ and we believe in openness, inclusiveness, having ambitions, making a difference and collaboration. You will play a role in the sensor part of the research section, interacting with
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consist of the following: Numerical simulation of multimode Raman interaction Mode excitation in optical fibers Characterize the modal purity of a multimode Raman amplifier Develop and implement spatial