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Field
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. The core objective is to develop advanced 3-D modelling and optimisation methodologies for magnetic components that enable accurate leakage inductance prediction and improved overall performance. Traditional
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to the eukaryotic cytoskeleton.[AB2] [BF3] [AB4] The thesis project will focus on electron microscopy (EM) method development. This by combining cryo-EM sample preparation, single particle and helical 3D
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exciton transport to the reaction center or to a donor-acceptor interface, respectively. Characterizing, modeling and improving exciton transport properties in molecular materials remain essential tasks in
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] [AB4] The thesis project will focus on electron microscopy (EM) method development. This by combining cryo-EM sample preparation, single particle and helical 3D reconstruction, as well as in situ
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conversion of 2D surface temperature measurements into 3D temperature fields. High-fidelity FEA models will be developed to generate the necessary data for constructing a novel temperature reconstruction
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techniques, which will take confocal and two-photon microscopes (the most widely used 3D imaging techniques) as a starting point. We plan to modify these techniques by enriching them with an array of single
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bind to protein ligands via sulphated residues that interact with positively charged regions within the protein ligand(s). The 3D organisation of these domains is therefore critical for their function
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such as the CowFIT 3D camera system through industry collaboration with VikingGenetics. This state-of-the-art system enables large-scale, non-invasive measurement of body weight in over 30,000 cows directly
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cultures—a powerful 3D ex vivo model—this project will dissect the mechanistic links between mTOR signalling, reactive glial phenotypes, and complement activation. The project will also incorporate human
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methods for biomedical and toxicological research Establishment and characterisation of 2D cell culture and 3D sphere models based on human primary cells and induced pluripotent stem cells (hiPSCs) Using