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Description of the offer : Are you ready to push the boundaries of materials science and technology? The Spintronics with chiraL hElimaGnetic InsulatOrs (SpinLEGO) group is excited to offer a unique
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, multiferroics, and spin liquids) to address current challenges in energy or information technologies. The position is suitable for candidates with academic backgrounds in chemistry, materials science
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magnetization dynamics in spintronic elements. Various computer programs, like first-principles methods (DFT and TDDFT) and code for simulations of out-of-equilibrium dynamics will be used. The applicant is
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modeling of electrically induced magnetization dynamics in spintronic elements. Various computer programs, like first-principles methods (DFT and TDDFT), simulations of out-of-equilibrium dynamics and
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|Co based multilayers) and metal-to-insulator transition materials (such as VOx) opens up a very interesting platform for the development of this technology. In a single multilayer it is possible
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demand for data storage and transfer between electronic devices (from data centers to personal computers, mobile phones to Internet of Things devices, etc.) necessitates denser and faster technology. In
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involved in instrumentation projects to improve the sensitivity of magnetization measurements in high pulsed magnetic fields. He/she will take in charge the preparation of the experiments and the data
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in nanostructures. Further information about the group can be found at https://sites.udel.edu/mbj/. With a state-of-the-art nanofabrication facility and a strong community in spintronics, photonics
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of such magnets, both uniform and propagating spin-wave modes. The researcher on this post will perform cutting edge microwave measurements with local experts and analyse the obtained data to interpret underlying
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- on sensory data processing and neuromorphic hardware is one of the most promising routes for AI applications. The project goal is to demonstrate that interconnected nanoscale skyrmionic-based systems are a