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Field
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time-scales: ab initio methods for the description of reaction processes, for the determination of electrochemical stabilities and for the optimisation of force fields; molecular dynamics simulations
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Your Job: You will join the "Electrocatalytic Interface Engineering" department, led by Prof. Dr.-Ing. Simon Thiele, and the "Membrane Polymer Synthesis" (MPS) team by Dr. Jochen Kerres
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the broader Complex Fluid group and focuses on areas of research bringing together complex fluids (e.g., polymer solutions) and microfluidics. For instance, we pioneered the use of polymer solutions to promote
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-free manufacturing of novel 3D-printable smart composite materials based on nature-derived polymers/elastomers is a prerequisite for the development of environmentally safe, mechanically resilient
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in analytical theory from Nancy and the long-standing experience in sophisticated computer simulation studies from Leipzig, promising unique prospects in advanced education of PhD students via research
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to their excellent structural performance and relatively low weight. However, their laminated structure results in low fracture toughness and limited impact resistance, influenced by the type of polymer used
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and experimental approaches, we will characterize the rheological properties of specific material component combinations and simulate and predict its performance in prototype flows. You will be part of
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bringing together complex fluids (e.g., polymer solutions) and microfluidics. For instance, we pioneered the use of polymer solutions to promote co-encapsulation of particles above the stochastic limit. We
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various therapeutic properties, though in many cases their mechanism of action is unclear. These polymers can also be formulated into structured fluids, which provide enhanced targeting and retention
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Computer-aided design (CAD) and additive manufacturing (3D printing) of architectured metamaterials Numerical modelling and simulation of the shock and impact behaviour of additively manufactured polymers