Highly tailorable, ultra-foldable, and resorbable thermoelectric paper for origami-enabled energy generation

Recently, owing to the increased focus on environmental initiatives such as the green campaign and green economy, thermoelectric (TE) energy harvesting technology using polymer-based TE materials has attracted significant attention. Among the various polymers used in TE materials, cellulose plays a...

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Bibliographic Details
Published in:Nano energy 2022-12, Vol.103, p.107824, Article 107824
Main Authors: Kim, Seoha, Na, Yujin, Nam, Chaeyoung, Jeong, Chang Kyu, Kim, Kyung Tae, Park, Kwi-Il
Format: Article
Language:English
Subjects:
Flexible electronics
Kirigami
Origami
Resorbable
Thermoelectric paper
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Summary:Recently, owing to the increased focus on environmental initiatives such as the green campaign and green economy, thermoelectric (TE) energy harvesting technology using polymer-based TE materials has attracted significant attention. Among the various polymers used in TE materials, cellulose plays a crucial role in substituting petroleum-based polymers as it is an abundant natural organic biomass resource. Herein, we first developed the origami and kirigami-enabled resorbable TE paper, with a self-assembled inorganic particle network layer below the cellulose polymer bio-matrix layer, through a simple drop-casting process. The prepared p- and n-type TE papers exhibited relatively high-power factor values of 3.11 and 1.16 μW·m−1·K−2, respectively, at 298 K. Furthermore, the fabricated flexible TE energy harvester (f-TEH) achieved an output performance of 38.55 mV, 12.14 μA, and 95.17 nW for a temperature difference of 24 K without the degradation of electrical and mechanical stability. Finally, we demonstrated the high applicability of TE papers in TEHs of complicated shapes by cutting or folding the materials and analyzing their TE performance. We believe that the results of this study not only present a breakthrough in designing tailorable and foldable TEHs for energy harvesting applications but also have significant implications in the field of green technology. [Display omitted] •Origami and kirigami-enabled resorbable thermoelectric (TE) paper is developed by using inorganic TE particles and cellulose.•p- and n-type TE papers exhibited relatively high-power factor values of 3.11 and 1.16 μW·m−1·K−2, respectively, at 298 K.•TE paper-based energy harvester showed the output performance of 38.55 mV, 12.14 μA, and 95.17 nW for a ΔT = 24 K.•The practical and industrial applicabilities of tailorable and foldable TE papers were verified.
ISSN:2211-2855
DOI:10.1016/j.nanoen.2022.107824