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activity at ETH Zurich in close collaboration with local and international clinical partners. Core research areas include: Design, modeling and performance assessment of medical and surgical robots Dexterous
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near-instantaneous proliferation of comb lines and new regimes of spectral control. Project background This project will combine advanced numerical modeling with laboratory demonstrations to explore
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Position: Bioprinting next generation functional tissues The field of tissue engineering and bioprinting is continually advancing to develop functional tissue models that more accurately mimic native tissue
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will develop and apply advanced methodologies, including scenario analysis and the innovative use of satellite data, to model the exposure and vulnerability of companies to climate-related hazards (e.g
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thoroughly analyzed with state-of-the-art theoretical models and published fully open access. The aim of our research is to advance the fundamental understanding of electrical insulation and current
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lack of rapid tools to understand and monitor the spread of pathogens. Building on our previous work on DNA tracing technologies, we aim to develop tools and procedures to model and monitor the spread
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, MATLAB, or similar tools. Experience in theoretical modelling (DFT, TDDFT, FDTD, COMSOL, etc.) is an advantage. Interest in scientific collaboration with experimental and theoretical groups. Ability
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learning to explore complex quantum systems, opening doors to advancements in fields like materials science and quantum chemistry. Similarly, quantum physicists are exploring the use of quantum effects
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combs that require large and complex setups, we aim to realize them directly on chip, using liquid-like light and schemes of lattices in synthetic frequency dimensions to achieve unprecedented stability