Microgel-enhanced thermal-sensitive hydrogel electrolyte enables active heat management, controllable energy storage and mechanical flexibility of supercapacitors

[Display omitted] •Supercapacitors containing microgel-enhanced thermal-sensitive hydrogel electrolytes are fabricated.•Hydrogel electrolyte enables active heat management, controllable energy storage and mechanical flexibility.•Thermal-switchable specific capacitance between 124 mF cm−2 and 9 mF cm...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-06, Vol.465, p.142923, Article 142923
Main Authors: Gao, Yang, Zhou, Hongwei, Zheng, Bohui, Wang, Zhao, Zhao, Guoxu, Zhang, Hongli, Liu, Hanbin, Jin, Xilang, Chen, Weixing, Ma, Aijie, Wu, Yuanpeng
Format: Article
Language:English
Subjects:
Controllable energy storage
Heat management
Hydrogel electrolyte
Microgel
Supercapacitor
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Summary:[Display omitted] •Supercapacitors containing microgel-enhanced thermal-sensitive hydrogel electrolytes are fabricated.•Hydrogel electrolyte enables active heat management, controllable energy storage and mechanical flexibility.•Thermal-switchable specific capacitance between 124 mF cm−2 and 9 mF cm−2 is achieved. Thermal runaway is a critical issue in energy storage process, leading to damage even failure of energy storage devices. Herein, active heat management, controllable energy storage and mechanical flexibility of supercapacitors are achieved by utilizing microgel-enhanced thermal-sensitive hydrogels as electrolytes. Because of the improved thermal sensitivity of microgel-enhanced hydrogel electrolyte, heat can be efficiently consumed by volume phase transition process, and meanwhile the energy storage process is also weakened by slowing down the ion transport. Reversibly controlled energy storage is also demonstrated in such supercapacitors. By varying temperature below and above volume phase transition temperature (VPTT) of hydrogel electrolytes, the specific capacitance is switched between 124 mF cm−2 and 9 mF cm−2. Moreover, the hydrogel electrolytes also endow such supercapacitors mechanical flexibility and stable charge–discharge under a bending angle from 0 to 180° has been demonstrated. Overall, this work has provided a new clue to construct intelligent hydrogel devices by elegant structure design.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2023.142923