Structure, stability and work functions of the low index surfaces of pure indium oxide and Sn-doped indium oxide (ITO) from density functional theory

Aron Walsh; C. Richard A. Catlow

doi:10.1039/c0jm01816c

Structure, stability and work functions of the low index surfaces of pure indium oxide and Sn-doped indium oxide (ITO) from density functional theory

Aron Walsh, C. Richard A. Catlow

Department of Materials Science and Engineering

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

166 Citations (Scopus)

Abstract

Indium sesquioxide is a transparent conducting oxide material widely used in photovoltaic and solid-state lighting devices. We report a study of the surface properties of the thermodynamically stable bixbyite phase of In ₂O₃ using density functional theory. The surface energies follow the order γ(100) > γ(110) > γ(111), with the charge neutral (111) termination being the lowest energy cleavage plane. The surface work functions (vertical ionisation potentials) are calculated using a non-local hybrid density functional, and show good agreement with recent experimental measurements. Finally, SnO₂ doping of the (111) surface is presented, where the Sn substitutions are more favourable on the surface sites and the excess electrons are delocalised amongst the In₂O ₃ conduction states; the enthalpy of solution is estimated to be 60 kJ mol^-1.

Original language	English
Pages (from-to)	10438-10444
Number of pages	7
Journal	Journal of Materials Chemistry
Volume	20
Issue number	46
DOIs	https://doi.org/10.1039/c0jm01816c
Publication status	Published - 2010 Dec 14

All Science Journal Classification (ASJC) codes

Chemistry(all)
Materials Chemistry

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abstract = "Indium sesquioxide is a transparent conducting oxide material widely used in photovoltaic and solid-state lighting devices. We report a study of the surface properties of the thermodynamically stable bixbyite phase of In 2O3 using density functional theory. The surface energies follow the order γ(100) > γ(110) > γ(111), with the charge neutral (111) termination being the lowest energy cleavage plane. The surface work functions (vertical ionisation potentials) are calculated using a non-local hybrid density functional, and show good agreement with recent experimental measurements. Finally, SnO2 doping of the (111) surface is presented, where the Sn substitutions are more favourable on the surface sites and the excess electrons are delocalised amongst the In2O 3 conduction states; the enthalpy of solution is estimated to be 60 kJ mol-1.",

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AU - Walsh, Aron

AU - Catlow, C. Richard A.

PY - 2010/12/14

Y1 - 2010/12/14

N2 - Indium sesquioxide is a transparent conducting oxide material widely used in photovoltaic and solid-state lighting devices. We report a study of the surface properties of the thermodynamically stable bixbyite phase of In 2O3 using density functional theory. The surface energies follow the order γ(100) > γ(110) > γ(111), with the charge neutral (111) termination being the lowest energy cleavage plane. The surface work functions (vertical ionisation potentials) are calculated using a non-local hybrid density functional, and show good agreement with recent experimental measurements. Finally, SnO2 doping of the (111) surface is presented, where the Sn substitutions are more favourable on the surface sites and the excess electrons are delocalised amongst the In2O 3 conduction states; the enthalpy of solution is estimated to be 60 kJ mol-1.

AB - Indium sesquioxide is a transparent conducting oxide material widely used in photovoltaic and solid-state lighting devices. We report a study of the surface properties of the thermodynamically stable bixbyite phase of In 2O3 using density functional theory. The surface energies follow the order γ(100) > γ(110) > γ(111), with the charge neutral (111) termination being the lowest energy cleavage plane. The surface work functions (vertical ionisation potentials) are calculated using a non-local hybrid density functional, and show good agreement with recent experimental measurements. Finally, SnO2 doping of the (111) surface is presented, where the Sn substitutions are more favourable on the surface sites and the excess electrons are delocalised amongst the In2O 3 conduction states; the enthalpy of solution is estimated to be 60 kJ mol-1.

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Structure, stability and work functions of the low index surfaces of pure indium oxide and Sn-doped indium oxide (ITO) from density functional theory

Abstract

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