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Are you intrigued by the forefront of biophysics technology – and integration with genome-wide data and AI methods? Thanks to groundbreaking advancements, we can now show the internal dynamics
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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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fields, with many potential applications in engineering and medicine. In this project, you will study the spatial control of biochemical signaling in intestinal organoids and other 2D cell cultures
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follow individual cells as they grow, move, and differentiate to form branched duct architectures in mammary gland organoids. Using advanced 3D imaging, genetic engineering, and AI-driven cell tracking
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professionalization and further development of the role of the NanoLab as national facility. You coordinate the acquisition of new equipment and the development of processes and new technology, based on your knowledge
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improves through the experimentation process. Qualifications The internship is open to master’s degree candidates from a range of backgrounds, including Engineering, Physics, Computer Science, Mathematics
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questions: 1) How can we atomically engineer metal nanoparticles through pulsed laser excitation? By being able to directly visualize light-induced atomic-scale changes in situ inside the TEM, you will target
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candidates with a strong background in chemistry, physics, materials science, or engineering with an interest in self-assembly phenomena. Excellent candidates with training in any area of science or
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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 (CL) microscopy, in which we use 1-30 keV electrons in a scanning electron microscope (SEM) to excite nanomaterials. The oscillating electric field...