The effect of co-adsorbed H2O2, CO2and H2O on CeO2nanoparticle morphology: A density-functional theory study

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

doi:10.1016/j.ceramint.2025.10.398

The effect of co-adsorbed H₂O₂, CO₂and H₂O on CeO₂nanoparticle morphology: A density-functional theory study

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

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

Abstract

CeO₂is an important catalyst for a variety of industrial and biomedical applications. Control over the morphology and surface speciation is key to obtaining the desired reactivity, but both are a complex function of the temperature and the partial pressures of oxygen and any adsorbates present. In this work, we combine first-principles calculations to model the individual and co-adsorption of H₂O₂, CO₂and/or H₂O at the {100}, {110} and {111} surfaces of stoichiometric and O-deficient CeO₂, and to explore the impact of environmental conditions on the morphology and surface speciation of CeO₂nanoparticles. We find that the presence of multiple adsorbates can render different particle morphologies accessible and stabilise or exclude adsorbates from the exposed surfaces. More generally, our modelling approach provides a powerful route to interpreting, predicting and optimising the catalytic behaviour of CeO₂, and one that can be readily extended to other materials and adsorbates.

Original language	English
Pages (from-to)	62540-62553
Number of pages	14
Journal	Ceramics International
Volume	51
Issue number	30 Part A
Early online date	29 Oct 2025
DOIs	https://doi.org/10.1016/j.ceramint.2025.10.398
Publication status	Published - 31 Dec 2025

Data Availability Statement

Data related to this research are available at https://doi.org/
10.17632/p69kcw334n.

Funding

We acknowledge the University of Huddersfield (UoH) EPSRC-DTP competition 2018–19 (EP/R513234/1) for funding SM. JMS is grateful to UK Research and Innovation (UKRI) for the award of a Future Leaders Fellowship (MR/T043121/1), and to the University of Manchester (UoM) 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.

Keywords

Cerium dioxide
COsurface adsorption
Fluorite oxides
HO surface adsorption
Nanoparticle morphology
Surface speciation

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Ceramics and Composites
Process Chemistry and Technology
Surfaces, Coatings and Films
Materials Chemistry

Access to Document

10.1016/j.ceramint.2025.10.398Licence: CC BY

Cite this

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title = "The effect of co-adsorbed H2O2, CO2and H2O on CeO2nanoparticle morphology: A density-functional theory study",

abstract = "CeO2is an important catalyst for a variety of industrial and biomedical applications. Control over the morphology and surface speciation is key to obtaining the desired reactivity, but both are a complex function of the temperature and the partial pressures of oxygen and any adsorbates present. In this work, we combine first-principles calculations to model the individual and co-adsorption of H2O2, CO2and/or H2O at the \{100\}, \{110\} and \{111\} surfaces of stoichiometric and O-deficient CeO2, and to explore the impact of environmental conditions on the morphology and surface speciation of CeO2nanoparticles. We find that the presence of multiple adsorbates can render different particle morphologies accessible and stabilise or exclude adsorbates from the exposed surfaces. More generally, our modelling approach provides a powerful route to interpreting, predicting and optimising the catalytic behaviour of CeO2, and one that can be readily extended to other materials and adsorbates.",

keywords = "Cerium dioxide, COsurface adsorption, Fluorite oxides, HO surface adsorption, Nanoparticle morphology, Surface speciation",

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

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AU - Moxon, Samuel

AU - Flitcroft, Joseph M.

AU - Skelton, Jonathan M.

AU - Gillie, Lisa J.

AU - Cooke, David J.

AU - Parker, Stephen C.

AU - Molinari, Marco

PY - 2025/12/31

Y1 - 2025/12/31

N2 - CeO2is an important catalyst for a variety of industrial and biomedical applications. Control over the morphology and surface speciation is key to obtaining the desired reactivity, but both are a complex function of the temperature and the partial pressures of oxygen and any adsorbates present. In this work, we combine first-principles calculations to model the individual and co-adsorption of H2O2, CO2and/or H2O at the {100}, {110} and {111} surfaces of stoichiometric and O-deficient CeO2, and to explore the impact of environmental conditions on the morphology and surface speciation of CeO2nanoparticles. We find that the presence of multiple adsorbates can render different particle morphologies accessible and stabilise or exclude adsorbates from the exposed surfaces. More generally, our modelling approach provides a powerful route to interpreting, predicting and optimising the catalytic behaviour of CeO2, and one that can be readily extended to other materials and adsorbates.

AB - CeO2is an important catalyst for a variety of industrial and biomedical applications. Control over the morphology and surface speciation is key to obtaining the desired reactivity, but both are a complex function of the temperature and the partial pressures of oxygen and any adsorbates present. In this work, we combine first-principles calculations to model the individual and co-adsorption of H2O2, CO2and/or H2O at the {100}, {110} and {111} surfaces of stoichiometric and O-deficient CeO2, and to explore the impact of environmental conditions on the morphology and surface speciation of CeO2nanoparticles. We find that the presence of multiple adsorbates can render different particle morphologies accessible and stabilise or exclude adsorbates from the exposed surfaces. More generally, our modelling approach provides a powerful route to interpreting, predicting and optimising the catalytic behaviour of CeO2, and one that can be readily extended to other materials and adsorbates.

KW - Cerium dioxide

KW - COsurface adsorption

KW - Fluorite oxides

KW - HO surface adsorption

KW - Nanoparticle morphology

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