Enhancing the thermoelectric performance of SnTe-CuSbSe2 with an ultra-low lattice thermal conductivity

Alloying SnTe with a well-designed secondary phase, particularly one with low lattice thermal conductivity, serves as an efficient route to realize excellent thermoelectric performance of inferior SnTe with intrinsically large thermal conductivity, which will eventually accelerate PbTe replacement....

Full description

Saved in:
Bibliographic Details
Published inJournal of materials chemistry. A, Materials for energy and sustainability Vol. 11; no. 8; pp. 4310 - 4318
Main Authors Xu, Huihong, Han, Wan, Xu, Rui, Hu, Zeqing, Liang, Xiaolong, Zhou, Li, Song, Jiming
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 21.02.2023
Subjects
Alloying
Dislocations
Electrical conductivity
Electrical resistivity
Heat conductivity
Heat transfer
Lead tellurides
Phonons
Point defects
Power factor
Reduction
Scattering
Seebeck effect
Thermal conductivity
Thermoelectricity
Tin tellurides
Transport properties
Online AccessGet full text

Cover

More Information
Summary:Alloying SnTe with a well-designed secondary phase, particularly one with low lattice thermal conductivity, serves as an efficient route to realize excellent thermoelectric performance of inferior SnTe with intrinsically large thermal conductivity, which will eventually accelerate PbTe replacement. Herein, the results validate that CuSbSe2 alloying (SnTe-CuSbSe2) can optimize the thermal transport properties of SnTe and help to advance the thermoelectric performance. Comprehensive evidence from microstructure characterization manifests that multifarious defects, such as Cu-based nanoprecipitates, dislocations and point defects, are induced into the SnTe matrix after CuSbSe2 alloying. These defects act as all-scale phonon scattering sources to achieve full-wavelength phonon scattering and promote a significant reduction in lattice thermal conductivity, and an ultra-low lattice thermal conductivity of 0.40 W m−1 K−1 is obtained for the SnTe-5% CuSbSe2 sample at 823 K. Moreover, deterioration in electrical conductivity also causes a related reduction in electronic thermal conductivity, thereby leading to a substantial reduction in the total thermal conductivity. In addition, the enhancement of m* originating from Cu and Sb doping rises the Seebeck coefficient in SnTe and guarantees a relatively competitive power factor. As a result, based on the significant reduction in the total thermal conductivity, as well as maintenance of the higher power factor, the SnTe-5% CuSbSe2 sample achieves a maximum ZT value of 1.1 at 823 K, which is greatly improved compared with the pristine counterpart (ZT = 0.5). These findings also reveal the tremendous prospect of boosting the thermoelectric performance of SnTe through CuSbSe2 and other I–V–VI2 compounds alloying.
ISSN:2050-7488
2050-7496
DOI:10.1039/d2ta09475d