Polyepitaxial grain matching to study the oxidation of uranium dioxide

Jacek Wasik; Joseph Sutcliffe; Renaud Podor; Jarrod Lewis; James Edward Darnbrough; Sophie Rennie; Syed Akbar Hussain; Christopher Bell; Daniel Alexander Chaney; Gareth Griffiths; Lottie Mae Harding; Florence Legg; Eleanor Lawrence Bright; Rebecca Nicholls; Yadukrishnan Sasikumar; Angus Siberry; Philip Smith; Ross Springell

doi:10.1038/s41529-024-00479-1

npj Materials Degradation (Jul 2024)

Polyepitaxial grain matching to study the oxidation of uranium dioxide

Jacek Wasik,
Joseph Sutcliffe,
Renaud Podor,
Jarrod Lewis,
James Edward Darnbrough,
Sophie Rennie,
Syed Akbar Hussain,
Christopher Bell,
Daniel Alexander Chaney,
Gareth Griffiths,
Lottie Mae Harding,
Florence Legg,
Eleanor Lawrence Bright,
Rebecca Nicholls,
Yadukrishnan Sasikumar,
Angus Siberry,
Philip Smith,
Ross Springell

Affiliations

Jacek Wasik: IAC, School of Physics, University of Bristol
Joseph Sutcliffe: IAC, School of Physics, University of Bristol
Renaud Podor: ICSM
Jarrod Lewis: IAC, School of Physics, University of Bristol
James Edward Darnbrough: IAC, School of Physics, University of Bristol
Sophie Rennie: IAC, School of Physics, University of Bristol
Syed Akbar Hussain: IAC, School of Physics, University of Bristol
Christopher Bell: IAC, School of Physics, University of Bristol
Daniel Alexander Chaney: IAC, School of Physics, University of Bristol
Gareth Griffiths: IAC, School of Physics, University of Bristol
Lottie Mae Harding: IAC, School of Physics, University of Bristol
Florence Legg: IAC, School of Physics, University of Bristol
Eleanor Lawrence Bright: IAC, School of Physics, University of Bristol
Rebecca Nicholls: IAC, School of Physics, University of Bristol
Yadukrishnan Sasikumar: Oak Ridge National Laboratory
Angus Siberry: IAC, School of Physics, University of Bristol
Philip Smith: IAC, School of Physics, University of Bristol
Ross Springell: IAC, School of Physics, University of Bristol

DOI: https://doi.org/10.1038/s41529-024-00479-1
Journal volume & issue: Vol. 8, no. 1
pp. 1 – 6

Abstract

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Abstract Although the principal physical behaviour of a material is inherently connected to its fundamental crystal structure, the behaviours observed in the real-world are often driven by the microstructure, which for many polycrystalline materials, equates to the size and shape of the constituent crystal grains. Here we highlight a cutting edge synthesis route to the controlled engineering of grain structures in thin films and the simplification of associated 3-dimensional problems to less complex 2D ones. This has been applied to the actinide ceramic, uranium dioxide, to replicate structures typical in nuclear fission fuel pellets, in order to investigate the oxidation and subsequent transformation of cubic UO2 to orthorhombic U3O8. This article shows how this synthesis approach could be utilised to investigate a range of phenomena, affected by grain morphology, and highlights some unusual results in the oxidation behaviour of UO2, regarding the phase transition to U3O8.

Published in npj Materials Degradation

ISSN: 2397-2106 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Materials of engineering and construction. Mechanics of materials
Website: https://www.nature.com/npjmatdeg/

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