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autonomous, energy-efficient, high-density BCIs. The PhD student will work on designing and testing all parts of this system, focusing on making it small, power-efficient, and suitable for medical or wearable
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environment. Colleagues come from diverse backgrounds and nationalities, creating an inclusive and inspiring atmosphere where knowledge sharing and interdisciplinary work are highly valued. The section has
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develop and create value using science and engineering to benefit society. That mission lives on today. DTU has 13,500 students and 6,000 employees. We work in an international atmosphere and have an
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you will design, build and operate advanced electrochemical systems focused on product detection. The project builds upon many years of experience - for example with the "sniffer chip" which has been
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undermine this future. Can you see how Machine Learning, Computer Vision, and Robotics can open up opportunities for autonomously operating agricultural robots? Are you passionate about making agriculture
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from diverse backgrounds and nationalities, creating an inclusive and inspiring atmosphere where knowledge sharing and interdisciplinary work are highly valued. The section has state-of-the art
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research environment with recently renovated laboratory facilities and state-of-the-art equipment for carbohydrate analytics and enzyme technology. Your daily work will take place in close collaboration with
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Senior Researcher in Synthetic Biology and Metabolic Engineering of power-to-X utilizing Microorg...
. We are seeking a Senior Researcher to lead pioneering work in synthetic biology and metabolic engineering, with a particular focus on non-model prokaryotic microorganisms capable of utilizing power
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to work in an international team, work with forefront methodologies, and contribute to the investigation of persistent, mobile and toxic substances in drinking water, then DTU and Norwegian University
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) and Technical University of Denmark (DTU) aims at understanding and designing noble metal clusters in the non-scalable regime to enable exceptional catalytic performance for e.g. methane and ammonia