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Field
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to uncover the role of structure in the glass transition and how the disordered structure of a glass gives rise to unique glass behaviour such as ageing and brittle mechanical failure. Unlike crystals which
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grow new materials by molecular beam epitaxy, or create heterostructures of materials by exfoliating and stacking atomically thin layers from crystals, and fabricate nanoscale electronic devices
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scaling limits of conventional silicon electronics. By engineering crystal symmetry and magnetic order through controlled chemical doping, the research aims to tune the quantum metric and realize giant
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crystals in real time using the technique of atomic force microscopy (AFM). We are the first group to use this approach to determine the nanoscale flexing transformation mechanism of a MOF induced by solvent
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precipitation, ion exchange, electrodialysis, and crystallization, configured into flexible process flow schemes. Duties As a PhD student you are expected to perform both experimental and theoretical work within
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phosphonate linkers preparation and crystallization of new MOF structures advanced synthetic methods, including work with air-sensitive compounds (Schlenk techniques) comprehensive characterization of materials
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the production of quasi-2D films obtained from polymeric liquid crystal phases and in their mechanical characterisation. Be available to implement and perform 3D printing of cellulosic liquid crystal systems and
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Starrydata2). The work will include the implementation of machine learning models (neural networks, random forests, SISSO), generative approaches for predicting crystal structures, the use of machine learning
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modeling methods for computational crystal plasticity. As this is an in-house position, there is teaching duties involved and this also requires decent knowledge of the German language besides English. You
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KB - PDF) Download METATUNE-MSCA-DN – DC13_Advanced control of wavefronts using liquid-crystals-based reconfigurable metasurfaces_Friedrich Schiller University Jena_Germany..pdf English (184.81 KB