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and optimize device architectures using finite element simulations. Fabricate prototypes using 3D printing, and cleanroom technologies. Implement test setups and assess devices performance through
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transformations in view of the targeted mechanical properties. These phase transformations occur during the metal forming processes in which they are shaped to a product. These need to be well controlled
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responses in vitro. Combined, these results will provide a unique insight into the sensory mechanisms underlying the coevolution of insect and plants, which is a major driving factor of biodiversity and has
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test their responses in vitro . Combined, these results will provide a unique insight into the sensory mechanisms underlying the coevolution of insect and plants, which is a major driving factor of
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department at TU/e for finite element-based deformable body simulations. Conduct research on mechanical contact processing models, integrating both physics-based numerical models and data-driven approaches
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the system dynamics as dictated by demand-side management. Input from consortium industry partners on component, operational and other costs will be used to validate the techno-economic models and quantify
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storage systems at any time interval required to capture the system dynamics as dictated by demand-side management. Input from consortium industry partners on component, operational and other costs will be
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and integrates two crucial elements for the breakthrough and impact of Additive Manufacturing: Standardization and Intellectual Property (IP). Aiming for both theoretical and practical contributions
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. The second sub-project, a postdoc track, focusses on pedagogies or structures for guiding students in selecting competencies to be achieved as learning outcomes, through learning activities and assessment
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culture of mutual support and collaboration between researchers. CML has two Departments: Industrial Ecology (CML-IE) and Environmental Biology (CML-EB). Presently, about 150 fte (including postdocs and