Thermoelectric properties of Cu2Se1−xTex solid solutions

Binary Cu 2 Se and Cu 2 Te have gained great attention recently because of their interesting and abnormal physical properties, such as ultralow thermal conductivity, high carrier mobility, large effective mass of carriers and excellent thermoelectric performance. In this study, we find that these tw...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2018, Vol.6 (16), p.6977-6986
Main Authors: Zhao, Kunpeng, Guan, Mengjia, Qiu, Pengfei, Blichfeld, Anders B, Eikeland, Espen, Zhu, Chenxi, Ren, Dudi, Xu, Fangfang, Iversen, Bo B, Shi, Xun, Chen, Lidong
Format: Article
Language:English
Subjects:
Carrier density
Carrier mobility
Copper selenides
Electrical resistivity
Heat conductivity
Heat transfer
Physical properties
Q factors
Seebeck effect
Solid solutions
Thermal conductivity
Thermoelectric materials
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Summary:Binary Cu 2 Se and Cu 2 Te have gained great attention recently because of their interesting and abnormal physical properties, such as ultralow thermal conductivity, high carrier mobility, large effective mass of carriers and excellent thermoelectric performance. In this study, we find that these two compounds are completely miscible throughout the studied composition range. The trigonal structure of Cu 2 Se is maintained when the Te content x is 0.2, but a new trigonal structure is formed when the Te content x is between 0.3 and 0.7. The carrier concentration is greatly improved when increasing the Te content in Cu 2 Se 1− x Te x solid solutions, resulting in a much reduced electrical resistivity and Seebeck coefficient in the whole temperature range as compared with those of binary Cu 2 Se. The total thermal conductivity is inversely increased due to the contribution from enhanced carrier thermal conductivity. As a result, the overall thermoelectric performance of Cu 2 Se 1− x Te x solid solutions lies between Cu 2 Se and Cu 2 Te. We also find that the quality factor of Cu 2 Se 1− x Te x is higher than those of most typical thermoelectric materials. Thus the thermoelectric performance can be further improved if the intrinsically high hole carrier concentrations can be reduced in Cu 2 Se 1− x Te x . We demonstrate that the quality factor of Cu 2 Se 1− x Te x solid solutions is higher than those of most typical thermoelectric materials.
ISSN:2050-7488
2050-7496
DOI:10.1039/c8ta01313f