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on: (i) direct carbonation of porous materials obtained from industrial fly ashes for CO₂ sequestration, and (ii) development, activation and characterization of low‑cost CO₂ adsorbents based on coal
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energy materials—and is equipped with state-of-the-art research facilities. Embedded in a dynamic network of industrial and academic collaborations, SIMaP provides an ideal environment for ambitious
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from KTH. The research environment includes, among others, three PhD students, two at KTH and one at Karlstad University and brings together solid mechanics and materials science in a dynamic research
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the underlying principles. For us, it is equally important to study the impact of materials on biological processes as well as the impact of biological processes on materials. Our ambition is to foster a dynamic
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applications such as energy-storage capacitors and electrostrictive actuators¹,². These relaxor materials are characterized by the presence of polar nanoregions (PNRs), in which electric dipoles are correlated
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investigations include material characterization, studies of fresh, young, and hardened concrete (including hydration), determination of the size distribution of air/macropores, capillary pores, and gel pores
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characterize their electromagnetic performance. To validate the achieved tuning range and functional performance in laboratory measurements against modeling and simulation results. This position is part of
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knowledge in General and Inorganic Chemistry along with an experience in the preparation/characterization of advanced inorganic materials and advanced oxidation processes (AOPs). The PhD. candidate must have
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with finite element modeling is essential. Experience with homogenized constrained-mixture models or other tissue growth models, and experience with mechanical characterization of biological materials is
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for the materiality of the built environment in defined regions, based on MFA and supported by BIM, GIS, IoT and AI technologies. Map existing anthropogenic material stocks and their dynamics and simulate circularity