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ways in which such physical learning is realized, and design new types of learning machines capable of solving complex engineering problems on their own. Some examples include neuromorphic computers
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between synthetic cells. With a lot of room for scientific creativity and collaborations, you will also further extend the capabilities of bottom-up synthetic biology by improving our methods to generate
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. The need for such a technology comes from the the extreme miniaturisation of micro-electronics, which places extreme demands not just on nanofabrication, but also on inspection methods that visualize
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to contribute to new technologies that realize radical improvements in the energy efficiency of information and communication technology? As part of the Dutch consortium NL-ECO on energy-efficient computing
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training, understanding and skill set in this expanding field. By integrating these approaches, you will provide insights of unprecedented detail, spanning from the cellular to the atomic level, from in vivo
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physics and design principles of natural and man-made complex matter, with research in the disciplines nanophotonics, nanophotovoltaics, chemistry & spectroscopy, mechanical metamaterials and biophysics
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and many other facilities. Qualifications You have a master’s degree in physics, chemistry, materials science, or a related field. You have very strong social, organizational, and communication skills
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Did you know high-energy electrons can serve as efficient sources of optical excitation of matter? Our group has developed cathodoluminescence microscopy, in which we use 1-30 keV electrons in a scanning electron microscope (SEM) to excite nanomaterials. The oscillating electric field carried by...