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collaboration with other departments. We research next-generation batteries, more efficient solar cells, more environmentally friendly hydrogen, and materials that can replace critical elements. In
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nanomaterials, specifically carbon dots, derived from plant-based resources, to replace non-sustainable incumbents in light-emitting applications, such as rare-earth-based phosphors and heavy-metal-based quantum
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geometries. However, AM-generated surfaces exhibit significant and highly irregular roughness, a key factor that strongly modifies turbulence, pressure drop, and heat transfer. Unlike conventional machined
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-sustainable incumbents in light-emitting applications, such as rare-earth-based phosphors and heavy-metal-based quantum dots. We will explore the potential of these sustainable luminescent nanomaterials in
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collaboration with other departments. We research next-generation batteries, more efficient solar cells, more environmentally friendly hydrogen, and materials that can replace critical elements. In
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parameters—including additive manufacturing—to component-level behavior and overall engine system performance using state-of-the-art MBSE methods and tools. Particular attention will be given to how
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emphasis on nanostructured electrodes, advanced electrolyte systems, and strategies for stabilizing metal anodes. We have a strong track record in developing innovative methods and extending characterization
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participatory environment are key elements in our growth. The 60 doctoral students within the department are a diverse group from different nationalities, backgrounds and fields. We offer very good employment
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-Interaction”. Our department conducts world-leading research in several scientific fields, and it has been growing rapidly in the recent years. An inclusive and participatory environment are key elements in our