Recent advances in enhancing thermoelectric performance of polymeric materials

被引:0
作者
Mulla, Rafiq [1 ]
Chapi, Sharanappa [1 ]
机构
[1] Department of Physics, B.M.S. College of Engineering, Bengaluru
来源
Polymers from Renewable Resources | 2024年 / 15卷 / 03期
关键词
energy conversion; flexible devices; polymer; Thermoelectric;
D O I
10.1177/20412479241266953
中图分类号
学科分类号
摘要
The inherent low thermal conductivity, low cost, and flexibility of polymeric materials make them potential candidates for thermoelectric applications. Their eco-friendliness and mechanical flexibility are useful for the design of portable and flexible self-powered electronics. However, the heat-to-electrical power conversion efficiency, also known as the figure-of-merit (ZT), of polymer TE materials is low. Research efforts are in progress to enhance the thermoelectric performance of polymers and to find new kinds of polymer composites. Recent research innovations, such as chemical doping of polymers, development of nanocomposites and hybrid composites, and nanostructuring have significantly changed the thermoelectric properties of the polymeric materials. In this article, we summarize the recent developments and achievements in polymer materials for thermoelectric applications. © The Author(s) 2024.
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收藏
页码:344 / 357
页数:13
相关论文
共 66 条
[1]  
Dennler G., Chmielowski R., Jacob S., Et al., Are binary copper sulfides/selenides really new and promising thermoelectric materials?, Adv Energy Mater, 4, (2014)
[2]  
He J., Tritt T.M., Advances in thermoelectric materials research: looking back and moving forward, Science, 357, (2017)
[3]  
Zhang Y., Heo Y.-J., Park M., Et al., Recent advances in organic thermoelectric materials: principle mechanisms and emerging carbon-based green energy materials, Polymers, 11, (2019)
[4]  
Mori T., Priya S., Materials for energy harvesting: at the forefront of a new wave, MRS Bull, 43, pp. 176-180, (2018)
[5]  
Koumoto K., Funahashi R., Guilmeau E., Et al., Thermoelectric ceramics for energy harvesting, J Am Ceram Soc, 96, pp. 1-23, (2013)
[6]  
Bell L.E., Cooling, heating, generating power, and recovering waste heat with thermoelectric systems, Science, 321, pp. 1457-1461, (2008)
[7]  
Mulla R., Glover K., Dunnill C.W., An easily constructed and inexpensive tool to evaluate the seebeck coefficient, IEEE Trans Instrum Meas, 70, pp. 1-7, (2021)
[8]  
Hewawasam L.S., Jayasena A.S., Afnan M.M.M., Et al., Waste heat recovery from thermo-electric generators (TEGs), Energy Rep, 6, pp. 474-479, (2020)
[9]  
Mulla R., Dunnill C.W., Powering the hydrogen economy from waste heat: a review of heat-to-hydrogen concepts, ChemSusChem, 12, pp. 3882-3895, (2019)
[10]  
Shi X.-L., Sun S., Wu T., Et al., Weavable thermoelectrics: advances, controversies, and future developments, Mater Futur, 3, (2024)
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