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Field
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also a pioneer in in situ 3D ED studies, as will be important in this project. More about us at our webpage . Position You will design and fabricate lithographically etched sample supports and MEMS
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and motion of hand captured by 3D/4D scanning to the mechanics of the textiles for exoskeleton design. 2. Build and experimentally evaluate textile exoskeletons using lab-based motion capture, pressure
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for culture and creative domains. These domains may include sound, music, visual art, 3D graphics, movement, or multimodal combinations thereof. The research will employ a mixed-methods approach: the search
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. The role of the PhD student at Empa will be the development of synthesis processes using light-based 3D printing of hydrogel-ceramic composites and the identification of process-structure-property
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developing AI methods for automated microstructure analysis and 3D microstructure generation. By combining self-supervised learning and diffusion-based generative models, the goal is to: Reconstruct high
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-material capability with a suitable closure model; (2) improved strategy for interface tracking/capturing; (3) very high-speed scenarios with use of nonlinear Riemann-solvers. If time allows exploratory 3D
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, through clever chemistry that attracts CO2 to the surfaces of 3D spongelike materials (such as metal-organic frameworks, or MOFs); and decarbonise the energy sector by designing new catalysts that will
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The TRR404 "Next Generation Electronics With Active Devices in Three Dimensions [Active-3D]" is a Collaborative Research Center/Transregio between TUD Dresden University of Technology and Rheinisch
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Tomography (CT) – two key NDT techniques used to inspect metallic and composite materials. These methods generate large 3D datasets that can be difficult for human experts to analyze manually, increasing
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their swimming dynamics and the mechanical deformations caused by the encapsulated active biomolecules, you will explore ways to control their motion in 3D space. Synthetic microswimmers have many potential