Improved thermoelectric performance in n-type flexible Bi2Se3+x/PVDF composite films

Qi Zou; Hongjing Shang; Daxing Huang; Taiguang Li; Bowei Xie; Hongwei Gu; Fazhu Ding

doi:10.20517/ss.2021.04

Soft Science ›› 2021, Vol. 1 ›› Issue (1) :2 DOI: 10.20517/ss.2021.04

Research Article

Improved thermoelectric performance in n-type flexible Bi₂Se_3+x/PVDF composite films

Qi Zou ¹^,²^,^#
, Hongjing Shang ¹^,²^,^#
, Daxing Huang ¹^,²
, Taiguang Li ¹^,²
, Bowei Xie ¹^,²
, Hongwei Gu ¹^,²
, Fazhu Ding ¹^,²

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Abstract

Bismuth selenide materials (Bi₂Se₃) have high performance around room temperature, demonstrating potential in thermoelectric applications. Presently, most vacuum preparation techniques used to fabricate the film materials, such as magnetron sputtering and molecular beam epitaxy, usually require complex and expensive equipment. This limits the practical applications of flexible thermoelectric films. Here, we prepared Bi₂Se_3+x nanoplate/polyvinylidene fluoride composite films with good flexibility using a facile chemical reaction method. Their thermoelectric performance and microstructures were systematically studied. The composite films exhibit a highly preferred orientation along (015). The carrier concentration and mobility were optimized by adding excessive element Se, eventually leading to an improvement in thermoelectric performance. The optimized power factor is 5.2 μW/K²m at 300 K. Furthermore, the performance remains stable after 2500 bending cycles at a radius of 1 cm, suggesting promising applications in wearable/portable electronics.

Keywords

Bi₂Se₃ / flexible / thermoelectric films / heterostructure

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Qi Zou, Hongjing Shang, Daxing Huang, Taiguang Li, Bowei Xie, Hongwei Gu, Fazhu Ding. Improved thermoelectric performance in n-type flexible Bi₂Se_3+x/PVDF composite films. Soft Science, 2021, 1(1): 2 DOI:10.20517/ss.2021.04

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