Effect of Diel Cycling Temperature, Relative Humidity, and Synthetic Route on the Surface Morphology and Hydrolysis of α-U(3)O(8)

[Image: see text] The speciation and morphological changes of α-U(3)O(8) following aging under diel cycling temperature and relative humidity (RH) have been examined. This work advances the knowledge of U-oxide hydration as a result of synthetic route and environmental conditions, ultimately giving novel insight into nuclear material provenance. α-U(3)O(8) was synthesized via the washed uranyl peroxide (UO(4)) and ammonium uranyl carbonate (AUC) synthetic routes to produce unaged starting materials with different morphologies. α-U(3)O(8) from UO(4) is comprised of subrounded particles, while α-U(3)O(8) from AUC contains blocky, porous particles approximately an order of magnitude larger than particles from UO(4). For aging, a humidity chamber was programmed for continuous daily cycles of 12 “high” hours of 45 °C and 90% RH, and 12 “low” hours of 25 °C and 20% RH. Samples were analyzed at varying intervals of 14, 24, 36, 43, and 54 days. At each aging interval, crystallographic changes were measured via powder X-ray diffraction coupled with whole pattern fitting for quantitative analysis. Morphologic effects were studied via scanning electron microscopy and 12-way classification via machine learning. While all samples were found to have distinguishing morphologic characteristics (93.2% classification accuracy), α-U(3)O(8) from UO(4) had more apparent change with increasing aging time. Nonetheless, α-U(3)O(8) from AUC was found to hydrate more quickly than α-U(3)O(8) from UO(4), which can likely be attributed to its larger surface area and porous starting material morphology.