Abstract
Nanometric hetero‐interfaces provide a wealth of scientific and engineering opportunities due to their complex and often misunderstood properties that can differ from their respective bulk constituents. In this work, the ability for engineered nanostructures within a bulk U─Mo alloy to arrest simulant fission products is investigated experimentally and computationally. Nanostructured 90 wt% U/ 10 wt% Mo (U‐10Mo) with 7.1 at% Nd is consolidated using spark‐plasma‐ sintering (SPS) techniques and is heat‐treated at 500 °C under vacuum for 24, 100, 500, and 1000 h. Analysis on the sintered and heat‐treated U‐10Mo reveals rapid kinetics in Nd diffusion to nanocluster sites, with evidence of Nd diffusion occurring during sintering and during the following heat‐treatment. The segregation behavior of Nd at two different U─Mo/UN interfaces is computationally verified using density functional theory (DFT) to reinforce experimental data.