Consecutive multimaterial printing of biomimetic ionic hydrogel power sources with high flexibility and stretchability

Consecutive multimaterial printing of biomimetic ionic hydrogel power sources with high flexibility and stretchability

Electric eel is an excellent example to harness ion-concentration gradients for sustainable power generation. However, current strategies to create electric-eel-inspired power sources commonly involve manual stacking of multiple salinity-gradient power source units, resulting in low efficiency, unst...

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Bibliographic Details
Published in:Nature communications Vol. 15; no. 1; pp. 5261 - 15
Main Authors: He, Pei, Yue, Junyu, Qiu, Zhennan, Meng, Zijie, He, Jiankang, Li, Dichen
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 19-06-2024
Nature Publishing Group
Nature Portfolio
Subjects:
639/166/987
639/301/1023/1025
639/301/299/161
639/301/930/1032
Biomimetics
Concentration gradient
Eels
Electric contacts
Electric potential
Filaments
Flexibility
Humanities and Social Sciences
Hydrogels
multidisciplinary
Power sources
Printers (data processing)
Printing
Science
Science (multidisciplinary)
Stretchability
Sustainable energy
Voltage
Wristwatches
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Summary:Electric eel is an excellent example to harness ion-concentration gradients for sustainable power generation. However, current strategies to create electric-eel-inspired power sources commonly involve manual stacking of multiple salinity-gradient power source units, resulting in low efficiency, unstable contact, and poor flexibility. Here we propose a consecutive multimaterial printing strategy to efficiently fabricate biomimetic ionic hydrogel power sources with a maximum stretchability of 137%. The consecutively-printed ionic hydrogel power source filaments showed seamless bonding interface and can maintain stable voltage outputs for 1000 stretching cycles at 100% strain. With arrayed multi-channel printhead, power sources with a maximum voltage of 208 V can be automatically printed and assembled in parallel within 30 min. The as-printed flexible power source filaments can be woven into a wristband to power a digital wristwatch. The presented strategy provides a tool to efficiently produce electric-eel-inspired ionic hydrogel power sources with great stretchability for various flexible power source applications. Electric eels are an excellent example of harnessing ion-concentration gradient for power generation. Here, authors demonstrate an automatic and high-throughput consecutive multi-material printing strategy to fabricate electric-eel-inspired ionic hydrogel power sources with high stretchability.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-49469-6