Oxygen point defect accumulation in single-phase U O2+x

Raul I. Palomares, Marshall T. McDonnell, Li Yang, Tiankai Yao, Jennifer E.S. Szymanowski, Joerg Neuefeind, Ginger E. Sigmon, Jie Lian, Matthew G. Tucker, Brian D. Wirth, Maik Lang

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Abstract

UO2.07 was characterized using neutron total scattering in order to elucidate defect morphology in the low oxygen-to-metal regime (x<0.125 for UO2+x). Data were collected at temperatures (600 and 1000 °C) coinciding with the single-phase UO2+x region of the established phase diagram, and results were compared with data of stoichiometric UO2 collected at near-identical temperatures. Experimental data were modeled and interpreted using a holistic approach employing a combination of analyses that characterized multiple spatial length scales. Preferential modeling of long-range atomic arrangements with Rietveld refinement suggests the existence of primarily monointerstitials in UO2.07, whereas preferential modeling of short-range atomic structures with small-box pair distribution function (PDF) refinement indicates the presence of defect clusters in UO2.07. Simultaneous modeling of multiple length scales using complementary reverse Monte Carlo (RMC) and molecular dynamics (MD) methods confirms that excess oxygen atoms in UO2.07 exist as small defects, such as monointerstitials and di-interstitials. RMC and MD results agree with diffraction analysis but differ significantly from small-box PDF refinements, which may be related to a lack of intermediate- and long-range structural information gained from the small-box PDF refinement procedure. Employing a combination of analysis methods with varying length-scale sensitivities enabled more accurate assessment of the UO2+x defect structure. Our findings provide experimental support for previously predicted di-interstitial defect morphologies in UO2+x that highly influence the accurate prediction of bulk physiochemical properties of UO2+x, such as oxygen diffusivity.

Original languageEnglish
Article number053611
JournalPhysical Review Materials
Volume3
Issue number5
DOIs
StatePublished - May 31 2019

Funding

This research was partially supported by the Office of Basic Energy Sciences of the US Department of Energy (DOE) as part of the Materials Science of Actinides Energy Frontier Research Center (DE-SC0001089). This work was partially funded by the University of Tennessee's Science Alliance Joint Directed Research Development program; a collaboration with Oak Ridge National Laboratory. L.Y. and B.W. acknowledge support by the US DOE, Office of Nuclear Energy (NE) and Office of Science (SC), Office of Advanced Scientific Computing Research (ASCR) through Scientific Discovery through Advanced Computing (SciDAC) program. J.L. acknowledges the financial support from the US DOE, Office of Nuclear Energy under a Nuclear Engineer University Program (Award No. DE-NE0008440). R.I.P. acknowledges support from the US DOE National Nuclear Security Administration (NNSA) through the Carnegie DOE Alliance Center (CDAC) under Grant No. DE-NA-0002006. The research at ORNL's Spallation Neutron Source was sponsored by the Scientific User Facilities Division, Office of Basic Energy Sciences, US DOE.

FundersFunder number
CDAC
Carnegie DOE Alliance Center
Nuclear Engineer University Program
Office of Basic Energy Sciences
Scientific User Facilities Division
US Department of Energy
University of Tennessee's Science Alliance
U.S. Department of EnergyDE-SC0001089
Office of Science
Office of Nuclear Energy
National Nuclear Security Administration
Advanced Scientific Computing Research
Oak Ridge National Laboratory

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