Thermoelectric performance of CuFeS2+2x composites prepared by rapid thermal explosion

Although many thermoelectric materials, such as Bi 2 Te 3 , PbTe and CoSb 3 , possess excellent thermoelectric properties, they often contain toxic and expensive elements. Moreover, most of them are synthesized by processes such as vacuum melting, mechanical alloying or solid-state reactions, which...

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Bibliographic Details
Published in:NPG Asia materials 2017-06, Vol.9 (6), p.e390-e390
Main Authors: Xie, Hongyao, Su, Xianli, Yan, Yonggao, Liu, Wei, Chen, Liangjun, Fu, Jiefei, Yang, Jihui, Uher, Ctirad, Tang, Xinfeng
Format: Article
Language:English
Subjects:
639/301/299/2736
639/766/25
Activated sintering
Biomaterials
Bulk sampling
Chemical synthesis
Chemistry and Materials Science
Energy Systems
Intermetallic compounds
Lead base alloys
Lead tellurides
Materials Science
Mechanical alloying
Optical and Electronic Materials
original-article
Phase boundaries
Phase transitions
Sintering
Structural Materials
Surface and Interface Science
Thermoelectric materials
Thin Films
Transport properties
Vacuum melting
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Summary:Although many thermoelectric materials, such as Bi 2 Te 3 , PbTe and CoSb 3 , possess excellent thermoelectric properties, they often contain toxic and expensive elements. Moreover, most of them are synthesized by processes such as vacuum melting, mechanical alloying or solid-state reactions, which are highly energy and time intensive. All these factors limit commercial applications of the thermoelectric materials. Therefore, it is imperative to develop efficient, inexpensive and non-toxic materials and explore rapid and low-cost synthesis methods. Herein we demonstrated a rapid, facile and low-cost synthesis route that combines thermal explosion (TE) with plasma-activated sintering and used it to prepare environmentally benign CuFeS 2+2 x . The phase transformation that occurred during the TE and correlations between the microstructure and transport properties were investigated. In a TE process, single-phase CuFeS 2 was obtained in a short time and the thermoelectric performance of the bulk samples was better than that of the samples that were synthesized using traditional methods. Furthermore, the effect of phase boundaries on the transport properties was investigated and the underlying physical mechanisms that led to an improvement in the thermoelectric performance were revealed. This work provides several new ideas regarding the TE process and its utilization in the synthesis of thermoelectric materials. Thermoelectric materials: embracing a big bang theory Thermoelectric materials can be rapidly formed into efficient structural phases using controlled thermal explosions. Many thermoelectric materials contain toxic and expensive elements and are synthesized by energy intensive processes. ’Fool's gold‘, or chalcopyrite, a copper iron sulfide (CuFeS 2 ) mineral, exhibits promising thermoelectric activity and a low toxicity. Xinfeng Tang from Wuhan University of Technology, China and co-workers have developed a quick process to arrange the atoms inside CuFeS 2 for optimal electrical conductivity and heat retention. Exposing powdered reagents in a quartz tube to brief periods of intense temperatures initiated a series of exothermic, explosive reactions that synthesized target crystals in under a minute. The researchers adjusted the initial sulfur content to fine tune the chalcopyrite crystal phases generated during explosions, and, following sintering, recovered one compound with 130% times the normal thermoelectric conversion efficiency. In a typical ther
ISSN:1884-4049
1884-4057
DOI:10.1038/am.2017.80