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lasting for 36 months. SPACER aims to develop new architectures for porous electrodes to improve the power density and energy efficiency of redox flow batteries (RFB), enabling affordable and durable long
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role in a vibrant group exploring the molecular mechanisms underpinning bacterial evolution and resistance. This fully-funded, full-time position combined with ETH's excellent working conditions, makes
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on bacterial biofilms, to start immediately or as per arrangement. The project The research group of Knut Drescher (https://drescherlab.org ) focuses on understanding the development and emergent
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on bacterial biofilms, to start immediately or as per arrangement. The project The research group of Knut Drescher (https://drescherlab.org ) focuses on understanding the development and emergent
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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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community. We develop and commercialize simulation tools, as well as measurement equipment for all-in-one electro-optical device characterization and for device stability assessment. Our R&D tools are used
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mechanisms developed will be validated in signal processing tasks for edge computing. Performance will be assessed in wearable domains and biomedical applications, with quantitative comparisons to conventional
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Your position Stacking and twisting atomically thin materials offers unprecedented control over their nanoscale magnetic, electronic, and optical properties. In this project, we will develop a novel
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of ceramic powder and the densification using the cold sintering processing method. The focus of the project is the development ferroelectric lead free ceramics sintered below 500°C and the analysis
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single electron spins in diamond as sensors to explore magnetic phenomena at the nanoscale. This doctoral project will center around the development and application of scanning magnetometry at ultra-low