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metal-oxide model systems with the potential use in modern technological areas such as heterogeneous catalysis, gas sensors and also as catalysts for fuel cells. The surface structure and morphology
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research facilities. The group is among the world-leading in solid-state electrochemistry and materials science of proton-conducting oxides for electrochemical energy conversion technologies such as proton
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seeking a highly motivated candidate with expertise in oxide material synthesis under inert atmospheres (Schlenk technique), physical chemistry, CO₂ reduction, and photoelectrochemical cells (PEC
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identify the target cells of the therapy (tubule vs. glomerulus, etc.) and potential regeneration niches, as well as metabolic modulations, oxidative stress, and other parameters that are difficult to assess
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of stacks with solid oxide cells (SOC) in electrolysis mode Electrochemical characterisation of cells during stack operation using direct and alternating current-based techniques (e.g. characteristic curves
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to the new Life Science Building by mid 2026 which offers modern research facilities. The Electrochemistry group is among the world-leading in solid-state electrochemistry and materials science of oxides
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electrocatalysts for ammonia/urea/methanol oxidation reaction to be used as the anode for direct ammonia/urea/methanol fuel cells. Develop electrocatalysts for the synthesis of ammonia or methanol at mild conditions
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of electrochemical cells (e.g., solid oxide fuel cells) or materials therein. Experience with analysis of electrical, kinetic or electrochemical properties, e.g., using isotope exchange techniques or electrochemical
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: Planning, implementation and evaluation of long-term and transient tests of stacks with solid oxide cells (SOC) in electrolysis mode Electrochemical characterisation of cells during stack operation using
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. Responsibilities and qualifications Your overall focus will be to advance next-generation solid oxide electrolysis cells by combining experimental degradation studies with advanced electrochemical impedance