Bidirectional energy filtering for electronic and phonon transport in Al2O3/ZnO superlattice films with anisotropy

Bidirectional energy filtering for electronic and phonon transport in Al2O3/ZnO superlattice films with anisotropy

Directional anisotropy transport in particular in nanostructured superlattice films could be crucial to understanding their thermoelectric properties, including figure-of-merit (ZT). However, few experimental studies have considered anisotropic properties in superlattice films. Therefore, this study...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 815; p. 152482
Main Authors: Lee, Won-Yong, Park, No-Won, Kang, Soo-Young, Kang, Min-Sung, Bui, Thi Thu Trang, Seok, Juhee, Kim, Gil-Sung, Saitoh, Eiji, Lee, Sang-Kwon
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 30-01-2020
Elsevier BV
Subjects:
Aluminum oxide
Anisotropy
Atomic layer epitaxy
Electron transport
Energy filtering
Filtration
Minority carrier blocking
Nanoscale columnar structure
Oxide semiconductor
Phonon scattering
Phonons
Properties (attributes)
Silicon dioxide
Silicon substrates
Superlattice films
Superlattices
Thermal conductivity
Zinc oxide
Oxide semiconductor
Superlattice films
Nanoscale columnar structure
Minority carrier blocking
Energy filtering
Phonon scattering
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Summary:Directional anisotropy transport in particular in nanostructured superlattice films could be crucial to understanding their thermoelectric properties, including figure-of-merit (ZT). However, few experimental studies have considered anisotropic properties in superlattice films. Therefore, this study investigated electronic and phonon transport anisotropy for atomic layer deposition Al2O3 (AO)/ZnO superlattice films on SiO2/Si substrates at 77–500 K using the four-point-probe 3-ω method and in-house Seebeck measurement system as a first step toward understanding corresponding superlattice film properties. In-plane and out-of-plane ZT values for AO/ZnO superlattice films were determined as 0.00017–0.19 and 0.00035–0.44, respectively, at 77–500 K. Higher ZT for both directions can be explained by synergistic combination of enhanced phonon scattering and bidirectional energy filtering in phonon and electronic transport compared to undoped ZnO films over the temperature range. We also found that out-of-plane thermal conductivity suppression was mostly attributable to increased ZT anisotropy in the out-of-plane direction rather than enhanced AO/ZnO superlattice film Seebeck and power factors. [Display omitted] •We examined electronic and phonon transport anisotropy of AO/ZnO superlattice films.•High ZT can be explained by synergistic combination of enhance phonon scattering and bidirectional energy filtering.•Out-of-plane thermal conductivity suppression is mostly attributed to increased ZT anisotropy of the superlattice films.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2019.152482