Transmutation of MAs and LLFPs with a lead-cooled fast reactor

Abstract: The management of nuclear wastes has long been a problem that hinders the sustainable and clean utilization of nuclear energy since the advent of nuclear power. These nuclear wastes include minor actinides (MAs: 237Np, 241Am, 243Am, 244Cm and 245Cm) and long-lived fission products (LLFPs: 79Se, 93Zr, 99Tc, 107Pd, 129I and 135Cs), and yet are hard to be handled. In this work, we propose a scheme that can transmute almost all the MAs and LLFPs with a lead-cooled fast reactor (LFR). In this scheme, the MAs and th… Show more

“…Transmutation of radionuclides have been considered as one of the potential solutions for managing high-level radioactive waste. Sun et al 12 proposed a new framework to transmute not only minor actinides but also long-lived fission products based on lead-cooled fact reactors. Using OpenMC, the optimal MA loading is evaluated based on the operation of the core, the neutron fux distribution, spectra, and k eff .…”

Long-term, sustainable solutions to radioactive waste management

“…Transmutation of radionuclides have been considered as one of the potential solutions for managing high-level radioactive waste. Sun et al 12 proposed a new framework to transmute not only minor actinides but also long-lived fission products based on lead-cooled fact reactors. Using OpenMC, the optimal MA loading is evaluated based on the operation of the core, the neutron fux distribution, spectra, and k eff .…”

Long-term, sustainable solutions to radioactive waste management

Enhancing transmutation rates of minor actinides using Zr and Y hydride and deuteride coatings in an LFR

Neutron capture cross section measurement of $$^{129}$$I and $$^{127}$$I using the NaI(Tl) spectrometer of the ANNRI beamline at J-PARC