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, ensuring stable operation even as system dynamics evolve. Recent advances in Modular Multilevel Converter (MMC) topologies, along with developments in battery and supercapacitor technologies, create new
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research will contribute to the accelerated discovery and optimisation of next-generation materials, with the flexibility to focus on applications such as advanced battery cathodes, nuclear waste
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in pursuing research in electrochemistry Previous experience with fuel cells, electrolyzers or redox flow batteries is a plus High motivation for pursuing a PhD within 3 years Excellent organizational
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for Risk Assessment is working on the project 'InViTOP - In vitro test battery for screening pro- and anti-osteoporotic effects of new drug candidates' in collaboration with Charité - Universitätsmedizin
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, thermal, electromagnetic or kinetic), are critical for the sustainable operation of wireless IoT devices and remote sensors. The world can reduce reliance on batteries and fossil-fuel-derived power if more
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We are searching for a doctoral candidate eager to take part in crossdisciplinarity work within battery technology for a sustainable future. This work will compose both theoretical and experimental
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architectures, and demonstration of showcase applications, like light emitters, light sensors, supercapacitors, and batteries. Research and training tasks will be carried out by a collaborative and
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(batteries, fuel cells, supercapacitors) o Microfluidic and lab-on-a-chip electrochemical platforms o Advanced electrode materials and surface modifications o In situ and operando electrochemical
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triboelectric nanogenerator (TENG) to sustainably power ingestible medical devices. The aim is to harness mechanical energy from natural intestinal peristalsis to enable battery-free operation of autonomous
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battery systems or distributed energy resources. This will include benchmarking data models, and deploying and testing these techniques in real-world, large-scale deployments. Contributing to setting