A Computational Study of doped olivine structured Cd2GeO4: local defect trapping of interstitial oxide ions

Adam McSloy; Paul Kelly; Peter Slater; P. M. Panchmatia

doi:10.1039/C6CP05436F

A Computational Study of doped olivine structured Cd₂GeO₄: local defect trapping of interstitial oxide ions

Adam McSloy, Paul Kelly, Peter Slater, P. M. Panchmatia

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Abstract

Computational modelling techniques have been employed to investigate defects and ionic conductivity in Cd2GeO4. We show due to highly unfavourable intrinsic defect formation energies the ionic conducting ability of pristine Cd2GeO4 is extremely limited. The modelling results suggest trivalent doping on the Cd site as a viable means of promoting the formation of the oxygen interstitial defects. However, the defect cluster calculations for the first time explicitly suggest a strong association of the oxide defects to the dopant cations and tetrahedral units. Defect clustering is a complicated phenomenon and therefore not trivial to assess. In this study the trapping energies are explicitly quantified. The trends are further confirmed by molecular dynamic simulations. Despite this, the calculated diffusion coefficients do suggest an enhanced oxide ion mobility in the doped system compared to the pristine Cd2GeO4.

Original language	English
Pages (from-to)	26284 - 26290
Number of pages	7
Journal	Physical Chemistry Chemical Physics
Volume	18
Issue number	37
Early online date	2 Sept 2016
DOIs	https://doi.org/10.1039/C6CP05436F
Publication status	Published - 7 Oct 2016

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McSloy_et_al_Computational_Study_Doped_Olivine_Structured_PCCP
Final Version of Record available at: http://dx.doi.org/10.1039/C6CP05436F Checked 10/10/2016
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title = "A Computational Study of doped olivine structured Cd2GeO4: local defect trapping of interstitial oxide ions",

abstract = "Computational modelling techniques have been employed to investigate defects and ionic conductivity in Cd2GeO4. We show due to highly unfavourable intrinsic defect formation energies the ionic conducting ability of pristine Cd2GeO4 is extremely limited. The modelling results suggest trivalent doping on the Cd site as a viable means of promoting the formation of the oxygen interstitial defects. However, the defect cluster calculations for the first time explicitly suggest a strong association of the oxide defects to the dopant cations and tetrahedral units. Defect clustering is a complicated phenomenon and therefore not trivial to assess. In this study the trapping energies are explicitly quantified. The trends are further confirmed by molecular dynamic simulations. Despite this, the calculated diffusion coefficients do suggest an enhanced oxide ion mobility in the doped system compared to the pristine Cd2GeO4.",

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AU - McSloy, Adam

AU - Kelly, Paul

AU - Slater, Peter

AU - Panchmatia, P. M.

PY - 2016/10/7

Y1 - 2016/10/7

N2 - Computational modelling techniques have been employed to investigate defects and ionic conductivity in Cd2GeO4. We show due to highly unfavourable intrinsic defect formation energies the ionic conducting ability of pristine Cd2GeO4 is extremely limited. The modelling results suggest trivalent doping on the Cd site as a viable means of promoting the formation of the oxygen interstitial defects. However, the defect cluster calculations for the first time explicitly suggest a strong association of the oxide defects to the dopant cations and tetrahedral units. Defect clustering is a complicated phenomenon and therefore not trivial to assess. In this study the trapping energies are explicitly quantified. The trends are further confirmed by molecular dynamic simulations. Despite this, the calculated diffusion coefficients do suggest an enhanced oxide ion mobility in the doped system compared to the pristine Cd2GeO4.

AB - Computational modelling techniques have been employed to investigate defects and ionic conductivity in Cd2GeO4. We show due to highly unfavourable intrinsic defect formation energies the ionic conducting ability of pristine Cd2GeO4 is extremely limited. The modelling results suggest trivalent doping on the Cd site as a viable means of promoting the formation of the oxygen interstitial defects. However, the defect cluster calculations for the first time explicitly suggest a strong association of the oxide defects to the dopant cations and tetrahedral units. Defect clustering is a complicated phenomenon and therefore not trivial to assess. In this study the trapping energies are explicitly quantified. The trends are further confirmed by molecular dynamic simulations. Despite this, the calculated diffusion coefficients do suggest an enhanced oxide ion mobility in the doped system compared to the pristine Cd2GeO4.

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JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

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A Computational Study of doped olivine structured Cd2GeO4: local defect trapping of interstitial oxide ions

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A Computational Study of doped olivine structured Cd₂GeO₄: local defect trapping of interstitial oxide ions