Strong and high-conductivity hydrogels with all-polymer nanofibrous networks for applications as high-capacitance flexible electrodes

Huimin He; Yaqing Chen; Aoyang Pu; Li Wang; Wenxiu Li; Xiaoyu Zhou; Chuyang Y. Tang; Kiwon Ban; Mengsu Yang; Lizhi Xu

doi:10.1038/s41528-024-00346-8

Strong and high-conductivity hydrogels with all-polymer nanofibrous networks for applications as high-capacitance flexible electrodes

Huimin He, Yaqing Chen, Aoyang Pu, Li Wang, Wenxiu Li, Xiaoyu Zhou, Chuyang Y. Tang, Kiwon Ban, Mengsu Yang^*, Lizhi Xu^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

24 Citations (Scopus)

36 Downloads (CityUHK Scholars)

Abstract

Flexible devices, such as soft bioelectronics and stretchable supercapacitors, have their practical performance limited by electrodes which are desired to have high conductivity and capacitance, outstanding mechanical flexibility and strength, great electrochemical stability, and good biocompatibility. Here, we report a simple and efficient method to synthesize a nanostructured conductive hydrogel to meet such criteria. Specifically, templated by a hyperconnective nanofibrous network from aramid hydrogels, the conducting polymer, polypyrrole, assembles conformally onto nanofibers through in-situ polymerization, generating continuous nanostructured conductive pathways. The resulting conductive hydrogel shows superior conductivity (72 S cm⁻¹) and fracture strength (27.2 MPa). Supercapacitor electrodes utilizing this hydrogel exhibit high specific capacitance (240 F g⁻¹) and cyclic stability. Furthermore, bioelectrodes of patterned hydrogels provide favorable bioelectronic interfaces, allowing high-quality electrophysiological recording and stimulation in physiological environments. These high-performance electrodes are readily scalable to applications of energy and power systems, healthcare and medical technologies, smart textiles, and so forth. © The Author(s) 2024.

Original language	English
Article number	56
Journal	npj Flexible Electronics
Volume	8
Online published	9 Sept 2024
DOIs	https://doi.org/10.1038/s41528-024-00346-8
Publication status	Published - 2024

Funding

The work was supported by grants from Hetao Shenzhen-Hong Kong Science and Technology Innovation Cooperation Zone Shenzhen Park Project (HZQB-KCZYZ-2021017), the central government-guided special funds for local scientific and technological development (226Z2603G), the Natural Science Foundation of Jiangsu Province (BK20241414), Research Grants Council (RGC) (Project 17200320, 17200722, 17201523, and C6004-22Y) and Environment and Conservation Fund (project 125/2021). This work was also supported by the Health@InnoHK program of the Innovation and Technology Commission of the Hong Kong SAR Government. The authors thank Professor Wending Pan for their assistance in the electrochemical characterization.

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abstract = "Flexible devices, such as soft bioelectronics and stretchable supercapacitors, have their practical performance limited by electrodes which are desired to have high conductivity and capacitance, outstanding mechanical flexibility and strength, great electrochemical stability, and good biocompatibility. Here, we report a simple and efficient method to synthesize a nanostructured conductive hydrogel to meet such criteria. Specifically, templated by a hyperconnective nanofibrous network from aramid hydrogels, the conducting polymer, polypyrrole, assembles conformally onto nanofibers through in-situ polymerization, generating continuous nanostructured conductive pathways. The resulting conductive hydrogel shows superior conductivity (72 S cm−1) and fracture strength (27.2 MPa). Supercapacitor electrodes utilizing this hydrogel exhibit high specific capacitance (240 F g−1) and cyclic stability. Furthermore, bioelectrodes of patterned hydrogels provide favorable bioelectronic interfaces, allowing high-quality electrophysiological recording and stimulation in physiological environments. These high-performance electrodes are readily scalable to applications of energy and power systems, healthcare and medical technologies, smart textiles, and so forth. {\textcopyright} The Author(s) 2024.",

author = "Huimin He and Yaqing Chen and Aoyang Pu and Li Wang and Wenxiu Li and Xiaoyu Zhou and Tang, {Chuyang Y.} and Kiwon Ban and Mengsu Yang and Lizhi Xu",

year = "2024",

doi = "10.1038/s41528-024-00346-8",

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T1 - Strong and high-conductivity hydrogels with all-polymer nanofibrous networks for applications as high-capacitance flexible electrodes

AU - He, Huimin

AU - Chen, Yaqing

AU - Pu, Aoyang

AU - Wang, Li

AU - Li, Wenxiu

AU - Zhou, Xiaoyu

AU - Tang, Chuyang Y.

AU - Ban, Kiwon

AU - Yang, Mengsu

AU - Xu, Lizhi

PY - 2024

Y1 - 2024

N2 - Flexible devices, such as soft bioelectronics and stretchable supercapacitors, have their practical performance limited by electrodes which are desired to have high conductivity and capacitance, outstanding mechanical flexibility and strength, great electrochemical stability, and good biocompatibility. Here, we report a simple and efficient method to synthesize a nanostructured conductive hydrogel to meet such criteria. Specifically, templated by a hyperconnective nanofibrous network from aramid hydrogels, the conducting polymer, polypyrrole, assembles conformally onto nanofibers through in-situ polymerization, generating continuous nanostructured conductive pathways. The resulting conductive hydrogel shows superior conductivity (72 S cm−1) and fracture strength (27.2 MPa). Supercapacitor electrodes utilizing this hydrogel exhibit high specific capacitance (240 F g−1) and cyclic stability. Furthermore, bioelectrodes of patterned hydrogels provide favorable bioelectronic interfaces, allowing high-quality electrophysiological recording and stimulation in physiological environments. These high-performance electrodes are readily scalable to applications of energy and power systems, healthcare and medical technologies, smart textiles, and so forth. © The Author(s) 2024.

AB - Flexible devices, such as soft bioelectronics and stretchable supercapacitors, have their practical performance limited by electrodes which are desired to have high conductivity and capacitance, outstanding mechanical flexibility and strength, great electrochemical stability, and good biocompatibility. Here, we report a simple and efficient method to synthesize a nanostructured conductive hydrogel to meet such criteria. Specifically, templated by a hyperconnective nanofibrous network from aramid hydrogels, the conducting polymer, polypyrrole, assembles conformally onto nanofibers through in-situ polymerization, generating continuous nanostructured conductive pathways. The resulting conductive hydrogel shows superior conductivity (72 S cm−1) and fracture strength (27.2 MPa). Supercapacitor electrodes utilizing this hydrogel exhibit high specific capacitance (240 F g−1) and cyclic stability. Furthermore, bioelectrodes of patterned hydrogels provide favorable bioelectronic interfaces, allowing high-quality electrophysiological recording and stimulation in physiological environments. These high-performance electrodes are readily scalable to applications of energy and power systems, healthcare and medical technologies, smart textiles, and so forth. © The Author(s) 2024.

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U2 - 10.1038/s41528-024-00346-8

DO - 10.1038/s41528-024-00346-8

M3 - RGC 21 - Publication in refereed journal

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JO - npj Flexible Electronics

JF - npj Flexible Electronics

M1 - 56

ER -

Strong and high-conductivity hydrogels with all-polymer nanofibrous networks for applications as high-capacitance flexible electrodes

Abstract

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