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Hauptverfasser: AbdulHameed, Mohamed, Schneider, Anton J., Beeler, Benjamin, Cooper, Michael W. D.
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2508.14329
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author AbdulHameed, Mohamed
Schneider, Anton J.
Beeler, Benjamin
Cooper, Michael W. D.
author_facet AbdulHameed, Mohamed
Schneider, Anton J.
Beeler, Benjamin
Cooper, Michael W. D.
contents Oxygen impurities in uranium nitride (UN) are reported to influence its swelling behavior under irradiation, yet the underlying mechanism remains unknown. In this work, we develop a first-principles model that quantifies the interaction of oxygen with voids and fission gas bubbles in UN, leading to a reduction in surface energy that can promote swelling. The analysis reveals that segregation of substitutional oxygen at surface nitrogen sites is the primary driver of surface energy reduction, $|Δσ|$, while oxygen in surface hollow sites plays a minor and sometimes counteracting role. $|Δσ|$ is most pronounced for small cavities ($R_v$ = 1--10 nm) at intermediate temperatures that coincide with the onset of breakaway swelling in UN. Larger voids require higher temperatures for oxygen adsorption to significantly lower their surface energy. The temperature dependence of $|Δσ|$ exhibits three regimes: negligible reduction at low temperatures due to sluggish oxygen diffusion, a maximum at intermediate temperatures where oxygen incorporation is optimal, and a decline at high temperatures due to enhanced bulk solubility. A parametric analysis reveals that $|Δσ|$ depends strongly on both oxygen concentration and cavity size, but is largely insensitive to porosity. Our results suggest that oxygen-induced surface energy reduction is essential for reconciling the mechanistic swelling model of UN with experimental observations.
format Preprint
id arxiv_https___arxiv_org_abs_2508_14329
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Modeling oxygen-void interactions in uranium nitride
AbdulHameed, Mohamed
Schneider, Anton J.
Beeler, Benjamin
Cooper, Michael W. D.
Materials Science
Oxygen impurities in uranium nitride (UN) are reported to influence its swelling behavior under irradiation, yet the underlying mechanism remains unknown. In this work, we develop a first-principles model that quantifies the interaction of oxygen with voids and fission gas bubbles in UN, leading to a reduction in surface energy that can promote swelling. The analysis reveals that segregation of substitutional oxygen at surface nitrogen sites is the primary driver of surface energy reduction, $|Δσ|$, while oxygen in surface hollow sites plays a minor and sometimes counteracting role. $|Δσ|$ is most pronounced for small cavities ($R_v$ = 1--10 nm) at intermediate temperatures that coincide with the onset of breakaway swelling in UN. Larger voids require higher temperatures for oxygen adsorption to significantly lower their surface energy. The temperature dependence of $|Δσ|$ exhibits three regimes: negligible reduction at low temperatures due to sluggish oxygen diffusion, a maximum at intermediate temperatures where oxygen incorporation is optimal, and a decline at high temperatures due to enhanced bulk solubility. A parametric analysis reveals that $|Δσ|$ depends strongly on both oxygen concentration and cavity size, but is largely insensitive to porosity. Our results suggest that oxygen-induced surface energy reduction is essential for reconciling the mechanistic swelling model of UN with experimental observations.
title Modeling oxygen-void interactions in uranium nitride
topic Materials Science
url https://arxiv.org/abs/2508.14329