Initialising ...
Initialising ...
Initialising ...
Initialising ...
Initialising ...
Initialising ...
Initialising ...
須藤 彩子; Meszaros, B.*; Poznyak, I.*; 佐藤 拓未; 永江 勇二; 倉田 正輝
Journal of Nuclear Materials, 533, p.152093_1 - 152093_8, 2020/05
被引用回数:4 パーセンタイル:45.45(Materials Science, Multidisciplinary)For a criticality assessment of the fuel debris generated by the Fukushima Daiichi Nuclear Power Plant accident, knowing the segregation of neutron absorber materials, , Gd, B, and Fe, in the fuel debris is necessary. Although B may mostly evaporate during melting, Fe and Gd are expected to remain in the molten corium. To understand the redistribution behavior of Gd and Fe during the solidification of the molten corium, solidification experiments with simulated corium (containing UO, ZrO, FeO, and GdO with a small amount of simulated fission products such as MoO, NdO, SrO, and RuO) were performed using a cold crucible induction heating method. The simulated corium was slowly cooled from 2,500C and solidified from the bottom to the top of the melt. An elemental analysis analysis of the solidified material showed that the Fe concentration in the inner region increased up to approximately 3.4 times that in the bottom region. This suggested that FeO might be concentrated in the residual melt and that, consequently, the concentration of Fe increased in the later solidification region. On the contrary, the Gd concentration in the periphery region was found to be approximately 2.0 times higher than that in the inner region, suggesting the segregation of Gd in the early solidified phase. No significant segregation was observed for the simulated fission products.