Nuclear Science and Techniques | 2021
Study on the production characteristics of 131I and 90Sr isotopes in a molten salt reactor
Abstract
The production of radionuclides 90 Sr and 131 I in molten salt reactors is an attractive option to address the global shortage of radionuclides. This study evaluated the production characteristics of 90 Sr and 131 I in a modular molten salt reactor, such as equilibrium time, yield, and cooling time of isotopic impurities. The fuel burn-up of a small modular molten salt reactor was analyzed by the Triton module of the scale program, and the variation in the fission yields of the two nuclides and their precursors with burn-up time. The yield of 131 I and 131 Te has been increasing during the lifetime. 131 I has an equilibrium time of about 40\xa0days, a saturation activity of about 40,300 TBq, and while 131 Te takes 250\xa0min to reach equilibrium, the equilibrium activity was about 38,000 TBq. The yields of 90 Sr and 90 Kr decreased gradually, the equilibrium time of 90 Kr was short, and 90 Sr could not reach equilibrium. Based on the experimental data of molten salt reactor experiment, the amount of nuclide migration to the tail gas and the corresponding cooling time of the isotope impurities under different extraction methods were estimated. Using the HF-H 2 bubbling method, 3.49\u2009×\u200910 5 TBq of 131 I can be extracted from molten salt every year, and after 13\xa0days of cooling, the impurity content meets the medical requirements. Using the electric field method, 1296 TBq of 131 I can be extracted from the off-gas system (its cooling time is 11\xa0days) and 109 TBq of 90 Sr. The yields per unit power for 131 I and 90 Sr is approximately 1350 TBq/MW and 530 TBq/MW, respectively, which shows that molten salt reactors have a high economic value.