Review-Fundamental Uranium Electrochemistry and Spectroscopy in Molten Salt Systems

Uranium is a key element used for nuclear energy production. Some advanced reactor designs, specifically molten salt reactors, will continue to use uranium as the fissile material for energy production. These new technologies require an intimate understanding of uranium chemistry during and after energy production. This review covers contemporary research on the coordination chemistry and behavior of uranium with the coolant and pyroprocessing salts as proposed for use in future reactor designs. Discussed topics include the nature of U redox reactions involving the reduction of U(III) to U metal and oxidation of U(III) to U(IV). These systems have been interrogated using cyclic voltammetry, chronopotentiometry, and optical and X-ray absorption spectroscopies. Insights obtained into the electrode potentials, the uranium species, and their diffusion coefficients in alkali halide melts from decades of research are summarized selectively. Perspectives are provided on the importance of unifying studies for comparison across multiple institutions. The application of synchrotron radiation research and multimodal approaches involving two (or more) probes, such as the widespread combination of UV-visible spectroscopy and electroanalysis known as spectroelectrochemistry, can provide new knowledge about the main process of uranium electrorefining-diffusion, as will be demonstrated in this review through the lack of comparable results.

Automated summary

Uranium is a critical element for nuclear energy production, particularly in advanced reactor designs like molten salt reactors. This review discusses research on the coordination chemistry and behavior of uranium with coolants and pyroprocessing salts, which are proposed for future reactor designs. Topics include the reduction and oxidation reactions of U(III) and the insights gained from techniques such as cyclic voltammetry and spectroscopy. The importance of unifying studies and utilizing synchrotron radiation research and multimodal approaches is also emphasized.