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projects, from engineering studies to the development of entire SW systems, with many years of experience working on programmes with space agencies such as ESA, NASA, CNES, DLR, etc. (https
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vivo tumor modeling, contributing to the project: “FSCN1 as a structural modulator of the cytoskeleton in T-cell lymphomas: molecular and functional bases.” This project combines molecular biology
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23 Dec 2025 Job Information Organisation/Company AMADE research institute - University of Girona Department Department of Mechanical Engineering and Industrial Construction Research Field
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of osteoarthritis). This project aims the following main objectives: Define patient-specific key functional and mechanical requirements for large osteochondral scaffolds. Produce biocompatible porous 3D structures
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of osteoarthritis). This project aims the following main objectives: Define patient-specific key functional and mechanical requirements for large osteochondral scaffolds. Produce biocompatible porous 3D structures
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and comprehensively characterize novel hyperfluorescent materials based on metal-organic frameworks (MOFs). These materials will be evaluated through chemical, structural, morphological, spectroscopic
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advanced materials with tailored functionalities, exploiting structural control at the atomic and nanometric level to engineer enhanced thermal and electronic performance. Our research spans organic and
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spin, orbital (including orbital Hall), and proximity effects (spin-orbit and exchange), which alter the band structure of the 2D materials and drive efficient torque and field-free switching. Recent
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perturbations. The candidate will explore how radiotherapy alters critical exponents, scaling behavior, and fixed-point structure within the model. Computational modelling and simulations will be key
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significant material: concrete. “Energy transitions” are intrinsically linked to materials, both historically and in the present. Concrete, the most widely used construction material, has expanded rapidly over