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techniques Advanced characterization methods, including synchrotron-based techniques, will be used to investigate materials under operating conditions and establish design principles for next-generation EOP
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micro and nano-technologies (characterization, simulation, modeling), as well as in the design and characterization of circuits, microsystems and systems. Located at the convergence of many sciences and
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, environmental sciences, or a related field. Strong knowledge of laboratory methods for the characterization of organic raw materials and fertilizers, including data analysis and interpretation. Practical
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spectroscopy for materials characterization. Preferred skills: Experience in solid-state NMR spectroscopy, DNP-enhanced NMR, applications of NMR to catalytic materials, and ability to work in a collaborative
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strong experience in materials synthesis and its physicochemical and electrochemical characterization. The work requires expertise in materials for electrochemical energy storage Duration: 12 months
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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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solid-state NMR spectroscopy enhanced by dynamic nuclear polarization to resolve these structures and quantify their size, distribution, and chemical composition in heterogeneous soft materials, and
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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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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