Evaluation of Sb-Nd and Te-Nd phases within the U-Zr fuel matrix and their interactions with HT9 alloy

Antimony (Sb) and tellurium (Te) were investigated as potential additives for U-10Zr (wt.%) metallic fuel to limit the fuel-cladding chemical interaction (FCCI) with HT-9 alloy. Neodymium (Nd) was utilized to simulate the formation of lanthanide-based solid fission products which are known to play a detrimental role in FCCI. Fuel alloys of U -Zr -Sb -Nd and U -Zr -Te -Nd were evaluated in their annealed condition and compared against their ascast conditions. Isothermal diffusion couple experiments were performed between U -Zr -Nd, U -Zr -Sb -Nd, and UZr -Te -Nd against the cladding alloy HT9 to evaluate the effectiveness of the additives to stabilize Nd within the fuel alloys, as well as investigate the interaction regions that form between the different fuel alloys and HT9. SbNd and Sb3Nd4, and TeNd are found to be the primary neodymium-based phases formed in the U -Zr -Sb -Nd and U -Zr -Te -Nd alloys, respectively. The zirconium-based phase, Zr2Sb, is also found to form within the former alloy. All phases were found to remain stable through the diffusion experiments and exhibited no interaction with HT9 constituent elements. Preferential interaction between Nd with additivities Te and Sb compared to constituting elements in HT9 was further verified based on density functional theory (DFT) calculated enthalpy of mixing.