-
Ensuring the safety of advanced reactor designs is one of the central challenges in developing next-generation nuclear technologies. Among these, Lead Fast Reactors (LFRs) stand out as promising candidates
-
, providing a unique opportunity to operate at the crossroads of sustainability, advanced materials, and nuclear safety, ultimately influencing technologies that will endure for generations. The scientific
-
radiation, even small deviations in beam delivery can have serious consequences for patient safety and public trust. As treatments become faster and more complex, from Intensity-Modulated Radiotherapy (IMRT
-
Reasonably Achievable) strategies, enhancing radiation safety. The goal of this project is to to make computational methods ready for official dosimetry, specifically for neutron, high energy and pulsed fields
-
ecosystems and groundwater. In addition, the current geopolitical context emphasizes Europe’s need for energy independence to ensure long-term energy security. Meanwhile, global demand is increasing with
-
Reactors (LFRs) stand out for their passive safety and efficient actinide management. The European EAGLES-300 initiative aims to commercialize a 350 MWe LFR-SMR by 2039, requiring advanced fuel technologies
-
Understanding nuclear fuel performance under irradiation is of paramount importance for the safety of nuclear energy applications in the context of current reactors generation (LWR), future generation (fast