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monitoring and control technologies applicable to molten salt and liquid metal systems Develop and test new materials and cell configurations for the production of salt and metal products. Perform experiments
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to synthesize these new materials. The candidate needs to be familiar with electrochemical testing and evaluating these materials. The successful candidate will be involved in concept and laboratory work
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, electrochemical floating tests, impedance spectroscopy, and battery performance testing Familiarity with in-situ characterization methods (e.g., FT-IR, XAS, TEM) to investigate interfacial reactivity and analyze
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oscillators driven by the storage-ring RF signals to fulfill the function of manipulating X-ray pulses. More specific responsibilities include MEMS design and simulation, testing and characterization
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electrorefining at engineering-scale to support industrialization. Develop and test new materials and electrochemical cell configurations. Perform innovative experiments and electroanalytical measurements (cyclic
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test results. Experience in nuclear-relevant separations approaches such as solvent extraction and other chemical techniques is desired. Hands-on experience working safely with radioactive materials in
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lithium-ion cathode material synthesis, electrochemical testing, and coin cell construction Experience with spectroscopic and microscopic techniques for structural analysis Solid understanding of lithium
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to play a leading role in at least one of these two aims, as well as participate in the development of experiments to test the methods. The multi-disciplinary team in this project includes researchers from
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into low-temperature electrolyzers, utilizing single-cell testing platforms to evaluate their device-level performance The position also entails extensive ex‐situ and operando characterization of low temperature
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simulation laboratory as well as supporting ongoing DOE projects. Candidates will be required to work in at least 4 of the following areas: Develop a functioning test bed using Opal-RT PHIL real-time platform