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tests and electrochemical operations with molten salts that may contain actinides and lanthanides within controlled atmosphere gloveboxes. Apply chemical thermodynamic and kinetic theories to understand
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. This exciting project focuses on further development of beam position monitoring structures and high gradient testing of components. They will play a key role in designing, fabricating, and testing advanced
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on securing a domestic supply chain for critical materials, such as graphite. This candidate will join a team developing and testing material beneficiation, leaching, and separation unit operations for carbon
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and electrorefining at engineering-scale. Develop and test new materials and electrochemical reactions. Perform innovative experiments and electroanalytical measurements (cyclic voltammetry
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accelerated material processing approaches Develop and test new materials and cell configurations. Perform experiments to understand and quantify reaction pathways and kinetics for molten salt systems
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, you will: Apply engineering principles to develop molten salt synthesis and separations processes to support fuel cycle science and technology. Develop and test new electrodes for use in molten salt
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testing of electro-optic (EO) devices integrated with photonic and microwave platforms Collaborate within a multidisciplinary team across CNM, the Advanced Photon Source (APS), Materials Science Division
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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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field Match at least one of the following profiles: Experience with modern AI methods for nuclear physics or high-energy physics detector data; or Hands-on work with PMTs, SiPMs, or MCP-PMTs (test-beam
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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