Thermodynamic calculations of oxygen self-diffusion in mixed-oxide nuclear fuels

D. C. Parfitt; M. W. D. Cooper; M. J. D. Rushton; S. -R. G. Christopoulos; M. E. Fitzpatricka; A. Chroneos

doi:10.1039/c6ra14424a

Thermodynamic calculations of oxygen self-diffusion in mixed-oxide nuclear fuels

D. C. Parfitt
, M. W. D. Cooper
, M. J. D. Rushton
, S. -R. G. Christopoulos
, M. E. Fitzpatricka
, A. Chroneos

Los Alamos National Laboratory
Imperial College London
Coventry University

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

Abstract

Mixed-oxide fuels containing uranium with thorium and/or plutonium may play an important part in future nuclear fuel cycles. There are, however, significantly less data available for these materials than conventional uranium dioxide fuel. In the present study, we employ molecular dynamics calculations to simulate the elastic properties and thermal expansivity of a range of mixed oxide compositions. These are then used to support equations of state and oxygen self-diffusion models to provide a self-consistent prediction of the behaviour of these mixed oxide fuels at arbitrary compositions.

Original language	Unknown
Pages (from-to)	74018-74027
Number of pages	10
Journal	RSC Advances
Volume	6
Issue number	78
DOIs	https://doi.org/10.1039/c6ra14424a
Publication status	Published - 29 Jul 2016
Externally published	Yes

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10.1039/c6ra14424a

Cite this

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abstract = "Mixed-oxide fuels containing uranium with thorium and/or plutonium may play an important part in future nuclear fuel cycles. There are, however, significantly less data available for these materials than conventional uranium dioxide fuel. In the present study, we employ molecular dynamics calculations to simulate the elastic properties and thermal expansivity of a range of mixed oxide compositions. These are then used to support equations of state and oxygen self-diffusion models to provide a self-consistent prediction of the behaviour of these mixed oxide fuels at arbitrary compositions.",

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AU - Parfitt, D. C.

AU - Cooper, M. W. D.

AU - Rushton, M. J. D.

AU - Christopoulos, S. -R. G.

AU - Fitzpatricka, M. E.

AU - Chroneos, A.

PY - 2016/7/29

Y1 - 2016/7/29

N2 - Mixed-oxide fuels containing uranium with thorium and/or plutonium may play an important part in future nuclear fuel cycles. There are, however, significantly less data available for these materials than conventional uranium dioxide fuel. In the present study, we employ molecular dynamics calculations to simulate the elastic properties and thermal expansivity of a range of mixed oxide compositions. These are then used to support equations of state and oxygen self-diffusion models to provide a self-consistent prediction of the behaviour of these mixed oxide fuels at arbitrary compositions.

AB - Mixed-oxide fuels containing uranium with thorium and/or plutonium may play an important part in future nuclear fuel cycles. There are, however, significantly less data available for these materials than conventional uranium dioxide fuel. In the present study, we employ molecular dynamics calculations to simulate the elastic properties and thermal expansivity of a range of mixed oxide compositions. These are then used to support equations of state and oxygen self-diffusion models to provide a self-consistent prediction of the behaviour of these mixed oxide fuels at arbitrary compositions.

U2 - 10.1039/c6ra14424a

DO - 10.1039/c6ra14424a

M3 - Erthygl

SN - 2046-2069

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EP - 74027

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