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have the opportunity to use advanced material characterization techniques (e.g., SEM, TEM, XRD, X-ray CT, rheology, and multiscale mechanical testing) to characterize the consequences of the activation
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hold an MSc degree (or equivalent) within Materials Science, Mechanical Engineering, or related field Experience with corrosion and metallurgy, electrochemical methods, microstructure analysis, and SEM
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diffraction and related scattering methods, Raman spectroscopy, electron microscopy (SEM and TEM). Carry out electrochemical characterization of the materials in half cells as well as in full sodium ion battery
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. You must demonstrate a strong background within at least 3 of the following topics: Metal additive manufacturing, especially laser powder bed fusion Microstructural characterization, such as XRD, SEM
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analysis, and SEM/EDS characterisation Strong analytical skills and knowledge of material failure mechanisms Proven ability to work across disciplines and collaborate with industrial and academic partners
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). Following the fate of your nanoparticles when applied onto the leaves (TEM, Cryo-SEM, AFM, chemical analysis, spectroscopy, etc). Studying and modelling the interactions of the applied nanoparticles
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cementitious materials using different techniques. Multi-scale characterization of the materials using e.g., SEM, RAMAN imaging, TEM, XRD, rheology, and multiscale mechanical testing. Lab-source and synchrotron
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to incorporate additional characterization data such as SEM, TEM, RAMAN, XRD data. Collaborate closely with an interdisciplinary team at DTU Compute, the DTU 3D Imaging Center and DTU Construct, in particular
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materials characterization techniques (e.g., SEM, EDS, hardness testing, microstructure analysis). Familiarity with welding or additive manufacturing processes (especially MIG-based or hybrid techniques