Interfacial advances yielding high efficiencies for thermoelectric devices

The development of thermoelectric (TE) applications is promising due to great advances achieved in recent decades; however, some limitations still exist in the implementation of TE power generation due to its inferior conversion efficiency ( η ) compared with that of its competitors. Significantly,...

Full description

Saved in:
Bibliographic Details
Published inJournal of materials chemistry. A, Materials for energy and sustainability Vol. 9; no. 6; pp. 329 - 323
Main Authors Wu, Wenjie, Ren, Guang-Kun, Chen, Xuxuan, Liu, Yinke, Zhou, Zhifang, Song, Jiangfeng, Shi, Yan, Jiang, Jia-Ming, Lin, Yuan-Hua
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 16.02.2021
Subjects
Devices
Electric contacts
Electrodes
Energy conversion efficiency
Figure of merit
Interface stability
Manufacturing industry
Materials selection
Oxidation
Sublimation
Thermal resistance
Thermoelectricity
Online AccessGet full text

Cover

More Information
Summary:The development of thermoelectric (TE) applications is promising due to great advances achieved in recent decades; however, some limitations still exist in the implementation of TE power generation due to its inferior conversion efficiency ( η ) compared with that of its competitors. Significantly, its low value is attributed to systematic issues, such as the TE performance of materials, electrode selection, and manufacturing process, resulting in a great challenge for its further enhancement. In this review, three different interfacial issues of TE devices are systematically investigated, and it is demonstrated that the related improvements will be beneficial for increasing their η values. Firstly, the mechanism and controlling approaches focusing on modifying the internal interface of materials remain significant for improving their figure of merit, ZT . Secondly, effective connections between TE elements and electrodes are a prerequisite, and matching optimal contact materials can provide a compatible interface with good stability, low contact electrical and thermal resistance. In addition, considering the long-term stable operation of devices, it is particularly critical to prevent the sublimation and oxidation of TE elements. These unique advances combined with the corresponding strategies demonstrate the potential of TE devices for large-scale power generation applications. Advances in material interface, electrode interface and protective layer interface demonstrate the potential of thermoelectric devices for large-scale power generation applications.
Bibliography:Jia-Ming Jiang worked as a Visiting Scholar during 2012-2014 in ITER, South France and then received his Ph.D. degree in Nuclear Science & Engineering in 2016 from Southwestern Institute of Physics, China. Since 2017, he has been working as an Assistant Researcher in East China University of Technology. His current interests focuses on physics, experimental engineering and numeric simulation research.
Wenjie Wu obtained his Bachelor's Degree in Nuclear Science & Engineering in 2018 from East China University of Technology, and is currently a Joint Training Postgraduate Student of East China University of Technology and China Academy of Engineering Physics. His current research focuses on the synthesis and characterization of new thermoelectric materials and devices.
Guang-Kun Ren received his Ph.D. Degree in Materials Science & Engineering in 2018 from Tsinghua University, China, and worked as a Visiting Scholar during 2016-2018 in the University of Washington, USA. Since 2020, he has been working as an associate professor at the China Academy of Engineering Physics. His expertise focuses on the synthesis and characterization of new thermoelectric materials and devices, heat transport and phonon scattering in solids, and gas sensing materials and devices.
ISSN:2050-7488
2050-7496
DOI:10.1039/d0ta06471h