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Field
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microswimmers/microrobots that can move and interact autonomously in 3D environments, mimicking the complex dynamics of microorganisms in fluids. Living systems such as bacteria or algae exhibit remarkable
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suitable for part-time employment. Starting date: 10.09.2025 Job description: You will have the following tasks: Modelling, design and simulation of shape memory alloy (SMA) microrobots Design and simulation
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FUNCTIONS: Cultures and co-cultures in 2D and 3D of cell lines and primary cultures derived from patient samples. Drug resistance assays in cell lines and primary culture derived from PDX or patient samples
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the microscale up. The developed technologies will be validated in half-cells and full working batteries at industrial partners at TRL 6. Our objectives: Multiscale modelling to better understand RFB behavior and
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. The developed technologies will be validated in half-cells and full working batteries at industrial partners at TRL 6. Our objectives: Multiscale modelling to better understand RFB behavior and identify optimal
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. The developed technologies will be validated in half-cells and full working batteries at industrial partners at TRL 6. Our objectives: Multiscale modelling to better understand RFB behavior and identify optimal
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, specifically battery prototypes. What you will do Multiscale modelling to better understand RFB behavior and identify optimal hierarchical shaped pore- and electrode-structure to encounter optimum electrolyte as
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involved in HORIZON-EIC Pathfinder project. This project combines rapid volumetric 3D printing technology with cell manipulation to create centimetre-long aligned cell constructs within hydrogels
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electrical conductivity. Implement the developed models and validate them against welding experiments. We are looking for a colleague who has experience in deriving and implementing numerical methods to solve 3D field
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reduction (MAR) algorithms, AI-based segmentation, and automated 3D anatomical modelling, promise clearer, more reliable imaging. Integrated effectively into clinical workflows, these advances have the