Charge Distribution in U1-xCexO2+y Nanoparticles.

Damien Prieur Jean-François Vigier Karin Popa Olaf WalterOliver DiesteZsolt VargaAaron BeckTonya Vitova Andreas C ScheinostPhilippe M Martin

Published in: Inorganic chemistry (2021)

In view of safe management of the nuclear wastes, a sound knowledge of the atomic-scale properties of U1-xMxO2+y nanoparticles is essential. In particular, their cation valences and oxygen stoichiometries are of great interest as these properties drive their diffusion and migration behaviors into the environment. Here, we present an in-depth study of U1-xCexO2+y, over the full compositional domain, by combining X-ray diffraction and high-energy resolution fluorescence detection X-ray absorption near-edge structure. We show, on one hand, the coexistence of UIV, UV, and UVI and, on the other hand, that the fluorite structure is maintained despite this charge distribution.

Keyphrases

electron microscopy
high resolution
single molecule
dual energy
healthcare
solar cells
ionic liquid
optical coherence tomography
loop mediated isothermal amplification
label free
walled carbon nanotubes
magnetic resonance imaging
risk assessment
heavy metals