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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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or more of the following areas: piezoelectric materials, MEMS/NEMS, finite element modelling (e.g., COMSOL), mechanical design, or energy harvesting. Hands-on experience with experimental characterization
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% of global freshwater consumption and the main driver of overexploitation of finite and vulnerable freshwater resources in many parts of the world. With the demand for food growing, geopolitical dynamics
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Specific Requirements A Master’s degree in Mechanical Engineering, Materials Science, or a closely related field with strong academic standing. Demonstrated expertise in finite element modeling, nonlinear
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, microfabrication, 3D-printing, finite element analysis, atomic force microscopy (AFM), microfluidics, optical microscopy, electron (cryo) microscopy, image analyis, statistical data analyis, and biophysics. You are
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. Preferably, you have experience in one or more of the following fields: scientific instrumentation, microfabrication, 3D-printing, finite element analysis, atomic force microscopy (AFM), microfluidics, optical
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models combined with the finite element method. Constitutive relations are required to describe material behavior. Advanced stainless steel typically possess complex microstructures across various length
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models combined with the finite element method. Constitutive relations are required to describe material behavior. Advanced stainless steel typically possess complex microstructures across various length
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. Experimental and theoretical skills in thermoplastic polymers and fiber reinforced composites, experience with polymer rheology is a plus. Experience with the finite element method and programming experience in