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simulation of technical systems Interest in practical work with catalysts, laboratory setups and pilot-scale plants Ability to analyse complex interrelationships and work methodically Good written and spoken
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Your Job: You will be part of a research team that applies high-throughput experimentation to accelerate research in the emerging field of electrocatalysis. Production of catalyst inks is one
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funded by a EU programme Is the Job related to staff position within a Research Infrastructure? No Offer Description By making catalysts ‘move’, their activity can increase up to 30×. A new piezoelectric
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field of electrocatalysis. Production of catalyst inks is one of the first steps along the development chain to new energy devices like fuel cells and electrolyzers. You will integrate and operate
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catalysts. An additional topic on cluster magnetism involves a systematic investigation of how magnetism of rare earth metal clusters is influenced by doping them with a few atoms of 3d transition metals. PhD
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of generating more efficient catalysts for olefin polymerization. These systems will be developed using surface organometallic chemistry, following three main research axes: • Investigating the reactivity of MAO
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electrocatalysis including quantitative product analysis, the synthesis of catalyst materials and in-situ analysis using electrochemical scanning tunnelling microscopy (EC-STM) Independent teaching in physical
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quantitative product analysis, the synthesis of catalyst materials, and in-situ analysis using electrochemical NAP-XPS Independent teaching Training and continuing education Administrative tasks Your profile
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hydrogen release by means of pressure control Carrying out parameter studies Comparison of different catalyst materials Determination of the pressure dependence of the dynamic hydrogen release Development
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-QM methodology on molecule-metal interfaces by simulating surface catalytic reactions and spectroscopy. This project will directly support molecular optoelectronics design and catalyst design research