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entire power grids. Extreme events with low return periods are especially important for power plants where 1 in 10,000 year risk levels are required to be mitigated for. Through collaboration with EDF
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. The developed methods will be evaluated in representative energy applications, including renewable energy systems (e.g., wind turbines), smart grids, and emerging electrified platforms such as electric ships
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offer a promising solution for this by enabling flexible charging that can reduce downtime and fixed costs, while increasing charging infrastructure utilization and mitigating peak grid impact. However
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autonomous energy supply in a world facing rising climate variability, grid disturbances, and increasing energy uncertainty. Designing such systems requires balancing performance, cost, resilience, and
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applications, including renewable energy systems (e.g., wind turbines), smart grids, and emerging electrified platforms such as electric ships or microgrids. Expected outcomes include novel methods for device
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analysis both locally and as part of the CMS computing Grid. The position offers exciting possibilities in the analysis of the new 13.6 TeV collision data towards quantum tomography of top quarks
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and EU-funded research projects, and has extensive know-how in 5G/6G communication platforms, IoT platforms, and Demand Response algorithms for the Smart Grid. IQU is also active in many EU-funded
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How do we build grid batteries that are cheap, safe and made from abundant materials? Zinc-ion batteries (ZIBs) are a promising answer – zinc is low-cost, non-toxic and works in water-based
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, they reinforce each other and are the driving force behind the technology we all use in our daily lives. Technology such as the electricity grid, which our faculty is helping to make completely sustainable and
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, they reinforce each other and are the driving force behind the technology we all use in our daily lives. Technology such as the electricity grid, which our faculty is helping to make completely sustainable and