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LNF: Fusion LiqUid meTals HYdrogen ExtRaction (Fusion LUTHYER): Difference between revisions
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LNF: Fusion LiqUid meTals HYdrogen ExtRaction (Fusion LUTHYER) (view source)
Revision as of 12:24, 31 October 2024
, 31 October 2024→Description of the project
(Created page with "== LNF - Nationally funded project == '''Title''': '''Fusion LiqUid meTals HYdrogen ExtRaction (Fusion LUTHYER)''' '''Reference''': PID2022-140644OA-I00 '''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022 '''Programme type (Modalidad de proyecto)''': Tipo A '''Area/subarea (Área temática / subárea)''': Energía y transporte '''Principal Investigator(s)''': Belit Garcinuño [https://orcid.org/0000-0003-3849-3122] '''Project typ...") |
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- ''Modelling activities in support of the experiments''. The modelling is an essential tool for the definition of the experiments. It compiles all physic-chemical processes with the operational parameters of the CLIPPER loop to obtain results in the limit of detection of the equipment and comparable to what is expected. One of the most attractive principles of nuclear fusion is that the radioactive waste produced in a commercial reactor should be classified as Low-Level Waste (LLW) within 100 years after the end of life (EOL). | - ''Modelling activities in support of the experiments''. The modelling is an essential tool for the definition of the experiments. It compiles all physic-chemical processes with the operational parameters of the CLIPPER loop to obtain results in the limit of detection of the equipment and comparable to what is expected. One of the most attractive principles of nuclear fusion is that the radioactive waste produced in a commercial reactor should be classified as Low-Level Waste (LLW) within 100 years after the end of life (EOL). | ||
-'' Analysis activities in support of the experiments''. | -'' Analysis activities in support of the experiments''. A proper characterization of the PbLi materials is fundamental not only for the development of tritium efficient extraction methods, but also for tritium inventory control. | ||
As a summary, the activities proposed in the framework of the Fusion LUTHYER project include a set of experimental and modeling tasks focused on some challenges in the liquid metals technology (PbLi) for its application to critical systems in the path to a DEMO reactor, as the tritium extraction system. | As a summary, the activities proposed in the framework of the Fusion LUTHYER project include a set of experimental and modeling tasks focused on some challenges in the liquid metals technology (PbLi) for its application to critical systems in the path to a DEMO reactor, as the tritium extraction system. | ||
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== References == | == References == | ||
# B. Garcinuño et al., “The CIEMAT LiPb Loop Permeation Experiment”, Fusion Eng. Des. 146 (2019) 1228-1232 | # B. Garcinuño et al., “The CIEMAT LiPb Loop Permeation Experiment”, Fusion Eng. Des. 146 (2019) 1228-1232 | ||