Origins of infrared transparency in highly conductive perovskite stannate BaSnO3

Origins of infrared transparency in highly conductive perovskite stannate BaSnO3

Near-infrared absorption in transparent conducting oxides (TCOs) is usually caused by electronic intraband transition at high doping levels. Improved infrared transparency is commonly explained by enhanced drift mobility in these TCOs. Here, an alternative cause behind the high infrared transparency...

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Main Authors: Y. Smirnov, J. Holovsky, G. Rijnders, M. Morales-Masis
Format: Article
Language:English
Published: AIP Publishing LLC 2020-06-01
Series:APL Materials
Online Access:http://dx.doi.org/10.1063/5.0010322
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spelling doaj-e13ad99ad646403bbc2903d1605666a22020-11-25T03:40:30ZengAIP Publishing LLCAPL Materials2166-532X2020-06-0186061108061108-610.1063/5.0010322Origins of infrared transparency in highly conductive perovskite stannate BaSnO3Y. Smirnov0J. Holovsky1G. Rijnders2M. Morales-Masis3MESA+ Institute for Nanotechnology, University of Twente, Enschede, 7500 AE, The NetherlandsInstitute of Physics, Czech Academy of Sciences, v. v. i., Cukrov1arnická 10, 162 00 Prague, Czech RepublicMESA+ Institute for Nanotechnology, University of Twente, Enschede, 7500 AE, The NetherlandsMESA+ Institute for Nanotechnology, University of Twente, Enschede, 7500 AE, The NetherlandsNear-infrared absorption in transparent conducting oxides (TCOs) is usually caused by electronic intraband transition at high doping levels. Improved infrared transparency is commonly explained by enhanced drift mobility in these TCOs. Here, an alternative cause behind the high infrared transparency of La-doped barium stannate (LBSO) transparent electrodes is presented. Following the Drude model formalism, we reconstructed spectrally resolved dielectric permittivity for a set of thin films with different free electron concentrations. A comparison of optical properties of LBSO with the tin-doped indium oxide thin films with identical carrier concentrations suggests that the redshift of the screened plasma wavelength for LBSO originates from its large high-frequency dielectric constant of 4.4, one of the highest reported for the s-orbital-based TCOs. Moreover, our measurements confirm an optical mobility significantly higher (>300 cm2/V s) than the drift mobility, effectively suppressing the free carrier absorption. These factors enable high infrared transparency of LBSO films and motivate further exploration of LBSO as broadband TCOs for solar cells and nanophotonics.http://dx.doi.org/10.1063/5.0010322
collection DOAJ
language English
format Article
sources DOAJ
author Y. Smirnov
J. Holovsky
G. Rijnders
M. Morales-Masis
spellingShingle Y. Smirnov
J. Holovsky
G. Rijnders
M. Morales-Masis
Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
APL Materials
author_facet Y. Smirnov
J. Holovsky
G. Rijnders
M. Morales-Masis
author_sort Y. Smirnov
title Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
title_short Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
title_full Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
title_fullStr Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
title_full_unstemmed Origins of infrared transparency in highly conductive perovskite stannate BaSnO3
title_sort origins of infrared transparency in highly conductive perovskite stannate basno3
publisher AIP Publishing LLC
series APL Materials
issn 2166-532X
publishDate 2020-06-01
description Near-infrared absorption in transparent conducting oxides (TCOs) is usually caused by electronic intraband transition at high doping levels. Improved infrared transparency is commonly explained by enhanced drift mobility in these TCOs. Here, an alternative cause behind the high infrared transparency of La-doped barium stannate (LBSO) transparent electrodes is presented. Following the Drude model formalism, we reconstructed spectrally resolved dielectric permittivity for a set of thin films with different free electron concentrations. A comparison of optical properties of LBSO with the tin-doped indium oxide thin films with identical carrier concentrations suggests that the redshift of the screened plasma wavelength for LBSO originates from its large high-frequency dielectric constant of 4.4, one of the highest reported for the s-orbital-based TCOs. Moreover, our measurements confirm an optical mobility significantly higher (>300 cm2/V s) than the drift mobility, effectively suppressing the free carrier absorption. These factors enable high infrared transparency of LBSO films and motivate further exploration of LBSO as broadband TCOs for solar cells and nanophotonics.
url http://dx.doi.org/10.1063/5.0010322
work_keys_str_mv AT ysmirnov originsofinfraredtransparencyinhighlyconductiveperovskitestannatebasno3
AT jholovsky originsofinfraredtransparencyinhighlyconductiveperovskitestannatebasno3
AT grijnders originsofinfraredtransparencyinhighlyconductiveperovskitestannatebasno3
AT mmoralesmasis originsofinfraredtransparencyinhighlyconductiveperovskitestannatebasno3
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