Ionic thermoelectric materials for near ambient temperature energy harvesting

Author(s)

Liu, Weishu; Qian, Xin; Han, Cheng-Gong; Li, Qikai; Chen, Gang

Abstract

Ionic thermoelectric (i-TE) materials, using ions as the energy carrier, can generate a voltage under a temperature difference, bearing similarities to the Seebeck effect of electrons and holes in solid-state materials. Recent experiments have demonstrated large thermopower of quasi-solid-state i-TE materials, which are attractive for harvesting ambient heat as large enough voltage can be generated under a small temperature difference to match the voltage input needs of sensors for internet-of-things applications. In this perspective article, we discuss similarities and differences of i-TE materials from electronic-based thermoelectric materials and also different i-TE thermoelectric effects including the thermodiffusion (Soret) effect and the thermogalvanic effect, in which the latter includes redox reaction entropy and the Soret effect. Strategies to improve performances of materials and devices are elaborated, together with needs for future research in understanding microscopic origins of different effects.

Date issued

2021-01-11

URI

https://hdl.handle.net/1721.1/165243

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Applied Physics Letters

Publisher

AIP Publishing

Citation

Weishu Liu, Xin Qian, Cheng-Gong Han, Qikai Li, Gang Chen; Ionic thermoelectric materials for near ambient temperature energy harvesting. Appl. Phys. Lett. 11 January 2021; 118 (2): 020501.

Version: Final published version