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Faculty of Engineering and Physical Sciences EPSRC Project Proposals 2025/26 (jobs.ac.uk) Project Link: Stress modulated antiferromagnetism in a BiFeO3-based thin film | Project Opportunities | PhD
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100%, Zurich, fixed-term The Nonlinear optics for Epitaxial growth of Advanced Thin films (NEAT) laboratory within the institute of Multifunctional Ferroic Materials in the Materials Department is
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NTNU 30th April 2025 Languages English English English We are looking for a PhD Candidate in Computational Modelling of Thin-Film Magnetic Materials Apply for this job See advertisement This is NTNU
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Rare-Earth-Sulfide thin films with enhanced Magneto-Optical properties Project Background: Nanostructured functional materials ranging from metals, metal oxides, metal nitrides and metal sulphides
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The growing demand for high-performance, low-power large-area CMOS technologies has driven interest in a range of new materials, including silicon-based thin films, organic semiconductors, and metal
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duties, up to a maximum of 20 per cent of full-time. Your research focus will be on models and simulations of reactive gas flows, with applications in thin film depositions. Thin films form the basis
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in the KU Leuven cleanroom and integrate MOF materials as functional coatings into these sensors. All aspects of sensor fabrication and evaluation will be explored, including methods for thin film
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for power applications. This will include advanced metrology, and interface processing, in conjunction with process optimisation for thin film dielectrics. This project is hosted by and use the full
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of order of OLED materials at the nanoscale in thin films, as well as how such order/disorder impacts the orientation and photoluminescence of emitter molecules. It will involve state-of-the-art OLED
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angular momentum currents for their use in innovative magnetic memory and computing applications. The devices will be fabricated by thin film sputtering growth and lithography in cleanroom facilities, and