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mechanisms of virus self-assembly. RNA-containing viruses are complex, nanometre sized particles with at their centre proteins covering the RNA. We want to find out how these complex assemblies are built up
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to specific domains or subsystems. Holistic system-level design is a necessary next-step because of the complexity of these systems. This implies going beyond current domain-specific solutions by combining
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the need to use any organic solvents. Here, the complexation of positively and negatively charged polyelectrolytes will be the basis for a new method for the fabrication of membranes, requiring only water as
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this research? The PhD will involve a lot of complex optical measurements with advanced custom-built microscopy, handling protein samples, surface chemistry and working with electric signals to trap and
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dispersion. Yet conventional Computational Fluid Dynamics (CFD) workflows rely on watertight geometric models and volumetric meshes that are slow, complex, and costly to produce. Within the POINT-TWINS project
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Are you fascinated by the large role software plays in the control of high-tech systems? Are you eager to contribute to improving supervisory controller development, and making it more structured
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the brain learns to deal with a larger social environment. The insights obtained from the research of Eveline Crone can help to structure education and society more effectively with a view to the
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we address the following steps/questions: Characterize the molecular structure and molecular distribution of suitable polymer pyrolysis waste streams to aid modelling of filler-matrix interfaces
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dynamics and learning in artificial and biological neural networks, with the aim of: Unveiling the link between network structure and neural representations. Understanding the impact of structural and
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high-tech sectors like aerospace, energy, and mobility. However, ensuring the mechanical reliability and structural integrity of printed metal parts remains a major obstacle for broader industrial