4.6 Article

High-performance, flexible thermoelectric generator based on bulk materials

Journal

CELL REPORTS PHYSICAL SCIENCE
Volume 3, Issue 3, Pages -

Publisher

CELL PRESS
DOI: 10.1016/j.xcrp.2022.100780

Keywords

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Funding

  1. Centers for Mechanical Engineering Research and Education at MIT
  2. SUSTech
  3. Guangdong Innovation Research Team Project [2016ZT06G587]
  4. Shenzhen Sci-Tech Fund [KYTDPT20181011104007]
  5. Tencent Foundation

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This study presents a bulk-material-based f-TEG with multifunctional copper electrodes and fabrics, which improves heat concentration, dissipation, comfort, and heat-leakage reduction. The results show that the f-TEG achieves high output power density and illumination performance under specific environmental conditions.
Flexible thermoelectric generators (f-TEGs) are promising solutions to power supply for wearable devices. However, the high fabrication costs and low output power density of conventional f-TEGs limit their applications. Here, we present a bulk-material-based f-TEG featuring multifunctional copper electrodes for heat concentration and dissipation and fabrics for comfort and heat-leakage reduction. When worn on the forehead, our f-TEG's maximum output power density (based on the device's area) reaches 48 mu W/cm(2) at a wind speed of 2 m/s and an ambient temperature of 15 degrees C. A light-emitting diode (LED) powered by our f-TEG headband with 100 pairs of thermoelectric pillars can illuminate a paper for reading in a dark room at 17.5 degrees C without an external heat sink or forced convection at the cold side. This work provides a general design approach for high-performance f-TEGs at a low cost. The device-level perspectives fill the critical knowledge gap between state-of-the-art material innovations and practical thermoelectric applications.

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