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Application of High-Throughput Seebeck Microprobe Measurements on Thermoelectric Half-Heusler Thin Film Combinatorial Material Libraries

Ziolkowski, Pawel und Wambach, Matthias und Ludwig, Alfred und Müller, Eckhard (2017) Application of High-Throughput Seebeck Microprobe Measurements on Thermoelectric Half-Heusler Thin Film Combinatorial Material Libraries. ACS Combinatorial Science. American Chemical society (ACS). doi: 10.1021/acscombsci.7b00019. ISSN 2156-8952.

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Kurzfassung

In view of the variety and complexity of thermoelectric (TE) material systems, combinatorial approaches to materials development come to the fore for identifying new promising compounds. The success of this approach is related to the availability and reliability of high-throughput characterization methods for identifying interrelations between materials structures and properties within the composition spread libraries. A meaningful characterization starts with determination of the Seebeck coefficient as a major feature of TE materials. Its measurement, and hence the accuracy and detectability of promising material compositions, may be strongly affected by thermal and electrical measurement conditions. This work illustrates the interrelated effects of the substrate material, the layer thickness, and spatial property distributions of thin film composition spread libraries, which are studied experimentally by local thermopower scans by means of the Potential and Seebeck Microprobe (PSM). The study is complemented by numerical evaluation. Material libraries of the half-Heusler compound system Ti–Ni–Sn were deposited on selected substrates (Si, AlN, Al2O3) by magnetron sputtering. Assuming homogeneous properties of a film, significant decrease of the detected thermopower Sm can be expected on substrates with higher thermal conductivity, yielding an underestimation of materials thermopower between 15% and 50%, according to FEM (finite element methods) simulations. Thermally poor conducting substrates provide a better accuracy with thermopower underestimates lower than 8%, but suffer from a lower spatial resolution. According to FEM simulations, local scanning of sharp thermopower peaks on lowly conductive substrates is linked to an additional deviation of the measured thermopower of up to 70% compared to homogeneous films, which is 66% higher than for corresponding cases on substrates with higher thermal conductivity of this study.

elib-URL des Eintrags:https://elib.dlr.de/119494/
Dokumentart:Zeitschriftenbeitrag
Titel:Application of High-Throughput Seebeck Microprobe Measurements on Thermoelectric Half-Heusler Thin Film Combinatorial Material Libraries
Autoren:
AutorenInstitution oder E-Mail-AdresseAutoren-ORCID-iDORCID Put Code
Ziolkowski, PawelGerman Aerospace Center, Institute of Materials Research, Köln, GermanyNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Wambach, MatthiasInstitute for Materials, Ruhr-University Bochum, Universitaetsstrasse 150, D-44801 Bochum, GermanyNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Ludwig, AlfredInstitute for Materials, Ruhr-University Bochum, Universitaetsstrasse 150, D-44801 Bochum, GermanyNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Müller, EckhardGerman Aerospace Center, Institute of Materials Research, Köln, Germany and Justus Liebig University Giessen, Institute of Inorganic and Analytical Chemistry, 35392 Giessen, GermanyNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Datum:21 Dezember 2017
Erschienen in:ACS Combinatorial Science
Referierte Publikation:Ja
Open Access:Ja
Gold Open Access:Nein
In SCOPUS:Ja
In ISI Web of Science:Ja
DOI:10.1021/acscombsci.7b00019
Verlag:American Chemical society (ACS)
ISSN:2156-8952
Status:veröffentlicht
Stichwörter:Combinatorial material development; half-Heusler compounds; high-throughput characterization; measurement accuracy; Potential and Seebeck Microprobe; Seebeck coefficient; spatial resolution; thermoelectric; thin films
HGF - Forschungsbereich:Luftfahrt, Raumfahrt und Verkehr
HGF - Programm:Raumfahrt
HGF - Programmthema:Technik für Raumfahrtsysteme
DLR - Schwerpunkt:Raumfahrt
DLR - Forschungsgebiet:R SY - Technik für Raumfahrtsysteme
DLR - Teilgebiet (Projekt, Vorhaben):R - Systemtechnologien (alt)
Standort: Köln-Porz
Institute & Einrichtungen:Institut für Werkstoff-Forschung > Thermoelektrische Materialien und Systeme
Hinterlegt von: Yasseri, Mohammad
Hinterlegt am:14 Nov 2019 17:10
Letzte Änderung:08 Nov 2023 15:03

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