Stoichiometry deviation in amorphous zirconium dioxide

Michael J. D. Rushton; Iuliia Ipatova; Lee J. Evitts; William E. Lee; Simon C. Middleburgh

doi:10.1039/C9RA01865D

Stoichiometry deviation in amorphous zirconium dioxide

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Abstract

Amorphous zirconia (a-ZrO2) has been simulated using a synergistic combination of state-of-the-art methods: employing reverse Monte-Carlo, molecular dynamics and density functional theory together. This combination has enabled the complex chemistry of the amorphous system to be efficiently investigated. Notably, the a-ZrO2 system was observed to accommodate excess oxygen readily – through the formation of neutral peroxide (O22−) defects – a result that has implications not only in the a-ZrO2 system, but also in other systems employing network formers, intermediates and modifiers. The structure of the a-ZrO2 system was also determined to have edge-sharing characteristics similar to structures reported in the amorphous TeO2 system and other chalcogenide-containing glasses.

Original language	English
Pages (from-to)	16320-16327
Journal	RSC Advances
Volume	9
Issue number	29
Early online date	24 May 2019
DOIs	https://doi.org/10.1039/C9RA01865D
Publication status	Published - 28 May 2019

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2019-Stoichiometry deviation in amorphous zirconium dioxideFinal published version, 934 KBLicence: CC BY

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title = "Stoichiometry deviation in amorphous zirconium dioxide",

abstract = "Amorphous zirconia (a-ZrO2) has been simulated using a synergistic combination of state-of-the-art methods: employing reverse Monte-Carlo, molecular dynamics and density functional theory together. This combination has enabled the complex chemistry of the amorphous system to be efficiently investigated. Notably, the a-ZrO2 system was observed to accommodate excess oxygen readily – through the formation of neutral peroxide (O22−) defects – a result that has implications not only in the a-ZrO2 system, but also in other systems employing network formers, intermediates and modifiers. The structure of the a-ZrO2 system was also determined to have edge-sharing characteristics similar to structures reported in the amorphous TeO2 system and other chalcogenide-containing glasses.",

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T1 - Stoichiometry deviation in amorphous zirconium dioxide

AU - Rushton, Michael J. D.

AU - Ipatova, Iuliia

AU - Evitts, Lee J.

AU - Lee, William E.

AU - Middleburgh, Simon C.

PY - 2019/5/28

Y1 - 2019/5/28

N2 - Amorphous zirconia (a-ZrO2) has been simulated using a synergistic combination of state-of-the-art methods: employing reverse Monte-Carlo, molecular dynamics and density functional theory together. This combination has enabled the complex chemistry of the amorphous system to be efficiently investigated. Notably, the a-ZrO2 system was observed to accommodate excess oxygen readily – through the formation of neutral peroxide (O22−) defects – a result that has implications not only in the a-ZrO2 system, but also in other systems employing network formers, intermediates and modifiers. The structure of the a-ZrO2 system was also determined to have edge-sharing characteristics similar to structures reported in the amorphous TeO2 system and other chalcogenide-containing glasses.

AB - Amorphous zirconia (a-ZrO2) has been simulated using a synergistic combination of state-of-the-art methods: employing reverse Monte-Carlo, molecular dynamics and density functional theory together. This combination has enabled the complex chemistry of the amorphous system to be efficiently investigated. Notably, the a-ZrO2 system was observed to accommodate excess oxygen readily – through the formation of neutral peroxide (O22−) defects – a result that has implications not only in the a-ZrO2 system, but also in other systems employing network formers, intermediates and modifiers. The structure of the a-ZrO2 system was also determined to have edge-sharing characteristics similar to structures reported in the amorphous TeO2 system and other chalcogenide-containing glasses.

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DO - 10.1039/C9RA01865D

M3 - Article

SN - 2046-2069

VL - 9

SP - 16320

EP - 16327

JO - RSC Advances

JF - RSC Advances

IS - 29

ER -

Stoichiometry deviation in amorphous zirconium dioxide

Abstract

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