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Optical properties of single crystalline SrMoO3 thin films

Radetinac, Aldin and Zimmermann, Jörg and Hoyer, Karoline and Zhang, Hongbin and Komissinskiy, Philipp and Alff, Lambert (2016):
Optical properties of single crystalline SrMoO3 thin films.
In: Journal of Applied Physics, AIP Publishing, pp. 055302, 119, (5), ISSN 0021-8979,
[Online-Edition: http://dx.doi.org/10.1063/1.4940969],
[Article]

Abstract

The optical properties of pulsed laser deposited highly crystalline SrMoO3 thin films were investigated. Due to their low resistivity below 30 μΩ cm, thin films of SrMoO3 are candidates for transparent conductor applications. The transparency of SrMoO3 extends into the ultraviolet range to about 300 nm. In this range, SrMoO3 has a higher transparency at similar sheet resistance as compared to alternative oxide or metallic materials. Density functional theory shows that electron-electron correlation effects are small in SrMoO3 as compared to other low-resistivity transition metal oxides and predicts the optical properties in good agreement with experiment.

Item Type: Article
Erschienen: 2016
Creators: Radetinac, Aldin and Zimmermann, Jörg and Hoyer, Karoline and Zhang, Hongbin and Komissinskiy, Philipp and Alff, Lambert
Title: Optical properties of single crystalline SrMoO3 thin films
Language: English
Abstract:

The optical properties of pulsed laser deposited highly crystalline SrMoO3 thin films were investigated. Due to their low resistivity below 30 μΩ cm, thin films of SrMoO3 are candidates for transparent conductor applications. The transparency of SrMoO3 extends into the ultraviolet range to about 300 nm. In this range, SrMoO3 has a higher transparency at similar sheet resistance as compared to alternative oxide or metallic materials. Density functional theory shows that electron-electron correlation effects are small in SrMoO3 as compared to other low-resistivity transition metal oxides and predicts the optical properties in good agreement with experiment.

Journal or Publication Title: Journal of Applied Physics
Volume: 119
Number: 5
Publisher: AIP Publishing
Divisions: 11 Department of Materials and Earth Sciences
11 Department of Materials and Earth Sciences > Material Science
11 Department of Materials and Earth Sciences > Material Science > Advanced Thin Film Technology
11 Department of Materials and Earth Sciences > Material Science > Theory of Magnetic Materials
Date Deposited: 26 Apr 2016 09:25
Official URL: http://dx.doi.org/10.1063/1.4940969
Identification Number: doi:10.1063/1.4940969
Funders: This work was supported by the Deutsche Forschungsgemeinschaft (DFG) within the Project KO 4093/1-1.
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