Facile synthesis of nanostructured n-type SiGe alloys with enhanced thermoelectric performance using rapid solidification employing melt spinning followed by spark plasma sintering

SiGe alloy is widely used thermoelectric materials for high temperature thermoelectric generator applications. However, its high thermoelectric performance has been thus far realized only in alloys synthesized employing mechanical alloying techniques, which are time-consuming and employ several mate...

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Bibliographic Details
Published in:Current applied physics 2018, 18(12), , pp.1540-1545
Main Authors: Vishwakarma, Avinash, Bathula, Sivaiah, Chauhan, Nagendra S., Bhardwaj, Ruchi, Gahtori, Bhasker, Srivastava, Avanish K., Dhar, Ajay
Format: Article
Language:English
Subjects:
Melt-spun
Rapid solidification
SiGe alloys
Spark plasma sintering
물리학
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Summary:SiGe alloy is widely used thermoelectric materials for high temperature thermoelectric generator applications. However, its high thermoelectric performance has been thus far realized only in alloys synthesized employing mechanical alloying techniques, which are time-consuming and employ several materials processing steps. In the current study, for the first time, we report an enhanced thermoelectric figure-of-merit (ZT) ∼ 1.1 at 900 °C in n-type Si80Ge20 nano-alloys, synthesized using a facile and up-scalable methodology consisting of rapid solidification at high optimized cooling rate ∼ 3.4 × 107 K/s, employing melt spinning followed by spark plasma sintering of the resulting nano-crystalline melt-spun ribbons. This enhancement in ZT > 20% over its bulk counterpart, owes its origin to the nano-crystalline microstructure formed at high cooling rates, which results in crystallite size ∼7 nm leading to high density of grain boundaries, which scatter heat-carrying phonons. This abundant scattering resulted in a very low thermal conductivity ∼2.1 Wm−1K−1, which corresponds to ∼50% reduction over its bulk counterpart and is amongst the lowest reported thus far in n-type SiGe alloys. The synthesized samples were characterized using X-ray diffraction, scanning electron microscopy and transmission electron microscopy, based on which the enhancement in their thermoelectric performance has been discussed. [Display omitted] •High cooling rate of melt-spun ∼ 3.4 × 107 K/s resulted in a crystallite size ∼ 7 nm.•Lower crystallite size drastically reduced the thermal conductivity ∼ 2.1 Wm−1K−1.•Figure of merit 1.1 at 900 °C and this enhancement is >20% over its bulk counterpart.
ISSN:1567-1739
1878-1675
DOI:10.1016/j.cap.2018.09.013