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listed below: Technical skills: You will receive a solid training in quantum sensing, optics, radio-frequency engineering, magnetism, cryogenics, data analysis and programming. Academic communication
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. For this purpose, the measurement procedure is to be enhanced, specified and validated so that the measurement setup can serve as a metrological reference laboratory for national and international partners
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stacking, both high performance and (very) high density can be achieved by this concept. The mission will be to explore, understand and develop the fundamental physics of device operation. This will require
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to microwaves, and will image the displacement of magnetic textures by currents, to quantify their efficiency in the generation of orbital currents and torques. Our approach will rely on the realization of new
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done using semiconducting materials, with transistors performing logical operations (“NOT”, “AND” etc.). A new paradigm proposes to use magnetic materials to perform these operations, by en-coding
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: micromagnetic simulation, conversion of theoretical data into experimental contrast and acquisition of experimental images. The work will be carried out by three teams: theory/simulation, spin textures within
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, and the fundamental physics of spintronic oscillators. Their work also explores the use of these oscillators in unconventional computing hardware, including neuromorphic systems, reservoir computing
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Description of the offer : During this PhD thesis, we propose to explore the properties of exotic antiferromagnetism, in non-collinear antiferromagnets like Mn3Sn or in altermagnets. We will image
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) — to join our team. You will be directly involved in developing and optimizing ion beam processes to improve device performance in MRAM and magnetic sensor applications. Beyond R&D, we are looking for a
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these nanocomposites, we are looking for a postdoc to further develop high performance computing numerical methods in our state-of-the-art open source micromagnetic model, MagTense. MagTense is based on a core