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of highly viscous fibre-based materials to improve their processability in conventional melt processing equipment. This understanding will enable the design of fibre-based materials as sustainable
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center for advanced research and one of Europe’s leading molecular biology laboratories, driving innovation in the life sciences. This creates an exciting platform with state-of-the-art infrastructure
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innovation in the life sciences. This creates an exciting platform with state-of-the-art infrastructure to conduct high-quality research, foster collaborations with other Swedish and international universities
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, we will identify optimal fast-charging parameters using data-driven optimization methods. (2) We will first design an optimal control strategy on laboratory three-electrode cells using anode potential
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involve dense research activities in the area of designing, experimenting and theoretical development with the following combined research areas linked with National, European and Worldwide R&D Projects
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phase-matching regimes, design innovative gas targets and laser-driven generation geometries to increase XUV yield. Successful achievement of these goals promises to revolutionize XUV light generation in
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-throughput computational screening methods for alloy design, experimental alloy production (casting and/or AM), testing and characterisation of the thermo-physical and mechanical properties of the designed
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travel combustion engines. The research involves computational thermodynamics (CALPHAD), high-throughput computational screening methods for alloy design, experimental alloy production (casting and/or AM
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environment focusing on engineering product development, innovation capability, and advanced engineering design, with strong links to industry and societal challenges. The research environment is characterised
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We invite applications for two fully funded, two-year postdoctoral positions in Materials Science, with a focus on the design and synthesis of sustainable, highly luminescent nanomaterials