Thermoelectric properties of in-situ plasma spray synthesized sub-stoichiometry TiO2−x

The thermoelectric properties of sub-stoichiometric TiO 2−x deposits produced by cascaded-plasma spray process are investigated from room-temperature to 750 K. Sub-stoichiometric TiO 2−x deposits are formed through in-situ reaction of the TiO 1.9 within the high temperature plasma flame and manipula...

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Bibliographic Details
Published in:Scientific reports 2016-11, Vol.6 (1), p.36581-36581, Article 36581
Main Authors: Lee, Hwasoo, Han, Su Jung, Chidambaram Seshadri, Ramachandran, Sampath, Sanjay
Format: Article
Language:English
Subjects:
639/301/299/2736
639/4077/4107
Deposits
Electrical conductivity
Fabrication
High temperature
Humanities and Social Sciences
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
MATERIALS SCIENCE
multidisciplinary
Plasma
Science
Temperature effects
Thermal conductivity
thermoelectric devices and materials
thermoelectrics
Titanium dioxide
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Summary:The thermoelectric properties of sub-stoichiometric TiO 2−x deposits produced by cascaded-plasma spray process are investigated from room-temperature to 750 K. Sub-stoichiometric TiO 2−x deposits are formed through in-situ reaction of the TiO 1.9 within the high temperature plasma flame and manipulated through introduction of varying amounts of hydrogen in the plasma. Although the TiO 2−x particles experience reduction within plasma, it can also re-oxidize through interaction with the surrounding ambient atmosphere, resulting in a complex interplay between process conditions and stoichiometry. The deposits predominantly contain rutile phase with presence of Magneli phases especially under significantly reducing plasma conditions. The resultant deposits show sensitivity to thermoelectric properties and under certain optimal conditions repeatedly show Seebeck coefficients reaching values of −230 μV K −1 at temperatures of 750 K while providing an electrical conductivity of 5.48 × 10 3  S m −1 , relatively low thermal conductivity in the range of 1.5 to 2 W m −1 K −1 resulting in power factor of 2.9 μW cm −1 K −2 . The resultant maximum thermoelectric figure of merit value reached 0.132 under these optimal conditions. The results point to a potential pathway for a large-scale fabrication of low-cost oxide based thermoelectric with potential applicability at moderate to high temperatures.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep36581