Non-stoichiometric and Subnano-heterogeneous Ln-incorporated UO2: its defect chemistry and thermal oxidation

TL;DR

This study investigates how different lanthanide elements and preparation conditions affect defect structures and oxidation behavior in UO2, providing insights into their potential use as advanced nuclear fuels.

Contribution

It offers a detailed analysis of defect chemistry and oxidation mechanisms in Ln-incorporated UO2, introducing a kinetic model and thermodynamic hypothesis for oxidation resistance.

Findings

Ce and U form close-to-ideal solid solutions and oxidize to (Ce, U)4O9.

Nd and U form solutions with oxygen vacancies under reducing conditions.

Gd and U exhibit short-range subnano-domain segregations.

Abstract

The defect chemistry and thermal oxidation of lanthanide (Ln) incorporated-UO2 are critical for understanding and predicting their behavior as enhanced fuels, mixed oxide (MOX) fuels, spent nuclear fuels (SNF), and particles for safeguard purposes. In this study, we independently controlled the Ln type (Ce4+, Nd3+, and Gd3+) and the preparation condition (reduced and nonreduced) to investigate their correlations to the generated non-equilibrated defects correspondingly. From early to late lanthanides: Ce and U formed close-to-ideal solid solutions in Fm-3m and oxidized to (Ce, U)4O9, Nd and U mixing under the reducing condition formed solid solutions with oxygen vacancies aggregating near Nd, and the mixing of smaller Gd with U resulted in short-range subnano-domain segregations with Ia-3 region embedded in the global Fm-3m matrix. Both trivalent Ln-incorporated UO2 oxidized to a mixture of (Ln, U)4O9 and (Ln, U)3O8. From these signature defect structures resulting from both Ln type and preparation condition, we proposed kinetic model and thermodynamic hypothesis for explaining the oxidation resistance of (Ln, U)O2. Although originated from f-block oxides, the discovery of long-range disorder short-range ordering may be not uncommon in other metal oxide systems, which can strongly influence their functionalities and properties.