Composition-dependent morphology of stoichiometric and oxygen deficient PuO2 nanoparticles in the presence of H2O and CO2: A density-functional theory study

Samuel Moxon; Joseph M. Flitcroft; Lisa J. Gillie; David J. Cooke; Jonathan M. Skelton; Stephen C. Parker; Marco Molinari

doi:10.1016/j.apsusc.2024.160997

Composition-dependent morphology of stoichiometric and oxygen deficient PuO₂ nanoparticles in the presence of H₂O and CO₂: A density-functional theory study

Samuel Moxon, Joseph M. Flitcroft, Lisa J. Gillie, David J. Cooke, Jonathan M. Skelton, Stephen C. Parker, Marco Molinari

Research output: Contribution to journal › Article › peer-review

1 Citation (SciVal)

Abstract

Among the most pressing challenges faced by the UK nuclear industry is how to safely handle its large stockpile of plutonium dioxide. In particular, understanding how the exposed surfaces interact with the environment is critical to establishing the chemical reactivity and determining suitable processing and storage conditions. In this work, we apply an ab initio modelling approach to predict the morphology and surface speciation of stoichiometric and oxygen deficient PuO₂ nanoparticles as a function of temperature and in the presence of individually- and co-adsorbed H₂O and CO₂. We find that co-adsorption of the two species has a significant impact on the surface composition, resulting in the equilibrium particle morphology being strongly dependent on the storage conditions. This work provides valuable insight into the behaviour of nanoparticulate PuO₂ in the presence of ubiquitous small molecules and marks an important step toward more realistic models extendable to other adsorbates and actinide oxides.

Original language	English
Article number	160997
Journal	Applied Surface Science
Volume	676
Early online date	21 Aug 2024
DOIs	https://doi.org/10.1016/j.apsusc.2024.160997
Publication status	Published - 15 Dec 2024

Data Availability Statement

Raw data is available from https://doi.org/10.17632/9pkcvm48z3

Funding

SM and MM acknowledge the 2018-19 University of Huddersfield (UoH) UK Engineering and Physical Sciences Research Council (EPSRC) DTP competition (EP/R513234/1). JMS acknowledges the UK Research and Innovation (UKRI) for the award of a Future Leaders Fellowship (MR/T043121/1), and the University of Manchester (UoM, UK) for the previous support of a UoM Presidential Fellowship. Calculations were run on the ARCHER and ARCHER2 UK National Supercomputing Services via our membership of the UK HEC Materials Chemistry Consortium (MCC; EPSRC EP/L000202/1, EP/R029431/1, EP/X035859/1). Analysis was performed on the Orion and Violeta computing facilities at UoH (UK).

Keywords

Actinide oxides
CO and HO co-adsorption
CO surface adsorption
HO surface adsorption
Nanoparticle morphology
Plutonium dioxide
Surface speciation

ASJC Scopus subject areas

Condensed Matter Physics
Surfaces and Interfaces
Surfaces, Coatings and Films

Access to Document

10.1016/j.apsusc.2024.160997Licence: CC BY

Cite this

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title = "Composition-dependent morphology of stoichiometric and oxygen deficient PuO2 nanoparticles in the presence of H2O and CO2: A density-functional theory study",

abstract = "Among the most pressing challenges faced by the UK nuclear industry is how to safely handle its large stockpile of plutonium dioxide. In particular, understanding how the exposed surfaces interact with the environment is critical to establishing the chemical reactivity and determining suitable processing and storage conditions. In this work, we apply an ab initio modelling approach to predict the morphology and surface speciation of stoichiometric and oxygen deficient PuO2 nanoparticles as a function of temperature and in the presence of individually- and co-adsorbed H2O and CO2. We find that co-adsorption of the two species has a significant impact on the surface composition, resulting in the equilibrium particle morphology being strongly dependent on the storage conditions. This work provides valuable insight into the behaviour of nanoparticulate PuO2 in the presence of ubiquitous small molecules and marks an important step toward more realistic models extendable to other adsorbates and actinide oxides.",

keywords = "Actinide oxides, CO and HO co-adsorption, CO surface adsorption, HO surface adsorption, Nanoparticle morphology, Plutonium dioxide, Surface speciation",

author = "Samuel Moxon and Flitcroft, {Joseph M.} and Gillie, {Lisa J.} and Cooke, {David J.} and Skelton, {Jonathan M.} and Parker, {Stephen C.} and Marco Molinari",

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T2 - A density-functional theory study

AU - Moxon, Samuel

AU - Flitcroft, Joseph M.

AU - Gillie, Lisa J.

AU - Cooke, David J.

AU - Skelton, Jonathan M.

AU - Parker, Stephen C.

AU - Molinari, Marco

PY - 2024/12/15

Y1 - 2024/12/15

N2 - Among the most pressing challenges faced by the UK nuclear industry is how to safely handle its large stockpile of plutonium dioxide. In particular, understanding how the exposed surfaces interact with the environment is critical to establishing the chemical reactivity and determining suitable processing and storage conditions. In this work, we apply an ab initio modelling approach to predict the morphology and surface speciation of stoichiometric and oxygen deficient PuO2 nanoparticles as a function of temperature and in the presence of individually- and co-adsorbed H2O and CO2. We find that co-adsorption of the two species has a significant impact on the surface composition, resulting in the equilibrium particle morphology being strongly dependent on the storage conditions. This work provides valuable insight into the behaviour of nanoparticulate PuO2 in the presence of ubiquitous small molecules and marks an important step toward more realistic models extendable to other adsorbates and actinide oxides.

AB - Among the most pressing challenges faced by the UK nuclear industry is how to safely handle its large stockpile of plutonium dioxide. In particular, understanding how the exposed surfaces interact with the environment is critical to establishing the chemical reactivity and determining suitable processing and storage conditions. In this work, we apply an ab initio modelling approach to predict the morphology and surface speciation of stoichiometric and oxygen deficient PuO2 nanoparticles as a function of temperature and in the presence of individually- and co-adsorbed H2O and CO2. We find that co-adsorption of the two species has a significant impact on the surface composition, resulting in the equilibrium particle morphology being strongly dependent on the storage conditions. This work provides valuable insight into the behaviour of nanoparticulate PuO2 in the presence of ubiquitous small molecules and marks an important step toward more realistic models extendable to other adsorbates and actinide oxides.

KW - Actinide oxides

KW - CO and HO co-adsorption

KW - CO surface adsorption

KW - HO surface adsorption

KW - Nanoparticle morphology

KW - Plutonium dioxide

KW - Surface speciation

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