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Field
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batteries (RFB), enabling affordable and durable long-duration energy storage. The approach is to use hierarchical structures, i.e. complex material layers that can be optimized to specific battery
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immobilisation, subject to final approval by the project sponsor. Your tasks Synthesis of metal-organic frameworks of the actinides (An-MOFs) Characterization of the An-MOFs' structure, porosity, as
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, microwave power, and frequency) on the degree and structure of carbonization and graphitization of the electrodes, aiming to reduce battery costs through process optimization. Additionally, the effects
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from the physics institute of Humboldt-Universität zu Berlin. Your responsibilities Development of QCLs (active regions) emitting in the range from 2 to 5 THz Optimization of resonator structures
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superstructures. Optimize NPL ligand shell structure in collaboration with TU Dresden to improve optical performance of NPL superstructures. Extend existing single-particle photophysical models of NPLs
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is to use hierarchical structures, i.e. complex material layers that can be optimized to specific battery chemistries and flow phenomena from the microscale up. The developed technologies will be
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of refrigerants superelastic shape memory alloys (mechanical, thermal, fatigue life) Modelling, design and characterization of test structures and devices (FEM multiphysics, lumped element modelling) Rapid
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used in satellites, but we aim to further develop it for sustainable, efficient, and cost-optimized electricity generation on Earth. For example, we are developing high-concentration solar modules, where
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the development of meta-optimization techniques that can automatically search for the best algorithm-hardware pair for a given problem. While we have a history of success in optimizing digital
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slow and inefficient. Our group develops methods and tools to automate the co-design process. The core of this project is the development of meta-optimization techniques that can automatically search