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Conducting glasses as new potential thermoelectric materials: the Cu–Ge–Te case

Recent approaches to improve performance of bulk thermoelectric (TE) materials show that they should have complex structures, include inclusions and impurities, possess mass fluctuations, disorder and be based on heavy elements. Glasses can possess these properties. In order to identify glasses with...

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Bibliographic Details
Published in:Journal of materials chemistry 2010-01, Vol.20 (8), p.1516-1521
Main Authors: Pereira Gonçalves, António, Branco Lopes, Elsa, Rouleau, Olivier, Godart, Claude
Format: Article
Language:English
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Summary:Recent approaches to improve performance of bulk thermoelectric (TE) materials show that they should have complex structures, include inclusions and impurities, possess mass fluctuations, disorder and be based on heavy elements. Glasses can possess these properties. In order to identify glasses with interesting TE potential, attention should be focused on small gap semiconducting or semitnetallic glasses. Chalcogenide glasses with Cu(x+y)Ge(20-x) Te(80-y) (0 , x , 20; 0 , y , 10) compositions were prepared by melt spinning. Their powder X-ray diffraction analyses point to a short-range order analogous to Ge(20)Te(80), with Cu atoms most likely replacing Ge atoms in the GeTe4 structural unit. It also indicates, together with the differential scanning calorimetry results, a reduction in the glass stability with the increase in Cu concentration. The enhancement of Cu content dramatically reduces (five orders of magnitude) the electrical resistivity, while keeping the Seebeck coefficients at large values (6400 kV K(-1)). As a consequence, a huge increase in the power factor is observed, up to a maximum value of 60 kW K(-2) m(-1) for the Cu(27.5)Ge(2.5)Te(70) glass at T = 300 K. Ge(20)Te(80) has extremely low lattice thermal conductivity values (60.1 W K(-1) m(-1) at 300 K), which points to relatively high values for the figure of merit ZT for this family of glasses, and indicates Cu(x+y), Ge(20-x)Te(80-y) based glasses as good candidates for obtaining high performance thermoelectric materials.
ISSN:0959-9428
1364-5501
DOI:10.1039/B908579C