Self-healing polymer dielectric exhibiting ultrahigh capacitive energy storage performance at 250 °C

Polymer dielectrics capable of operating at elevated temperatures are essential components in advanced electronics and electrical power systems. However, dielectric polymers generally display significantly deteriorated capacitive performance at high temperatures because of exponential growth of elec...

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Bibliographic Details
Published in:Energy & environmental science 2024-11, Vol.17 (22), p.8866-8873
Main Authors: Xu, Wenhan, Yang, Fei, Zhao, Guodong, Zhang, Shixian, Rui, Guanchun, Zhao, Muchen, Liu, Lingling, Chen, Long-Qing, Wang, Qing
Format: Article
Language:English
Subjects:
Anderson localization
Charge efficiency
Conduction
Copolymers
Dielectrics
Discharge
Displays
Electric power
Electric power systems
Electrical conduction
Energy charge
Energy storage
High temperature
Localization
Polymers
Self healing materials
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Summary:Polymer dielectrics capable of operating at elevated temperatures are essential components in advanced electronics and electrical power systems. However, dielectric polymers generally display significantly deteriorated capacitive performance at high temperatures because of exponential growth of electrical conduction. Here we design and prepare the cross-linked copolymers with interrupted translational symmetry and the use of local disorder-induced electron localization ( i.e. , Anderson localization) to impede electrical conduction of the copolymers. Consequently, the copolymer exhibits state-of-the-art discharged energy density of 3.5 J cm −3 with a charge-discharge efficiency of 90% at 250 °C. The copolymer also displays much more stable capacitive energy storage performance in the temperature range of 25 to 250 °C compared to existing dielectric polymers. With the demonstrated breakdown self-healing ability and excellent cyclability of the copolymer, this work sheds a new light on the design of high-temperature high-energy-density polymer dielectrics. The Anderson localization effect has been exploited in the design of high-temperature dielectric polymers, resulting in reduced conduction loss and outstanding capacitive energy storage performance over a wide temperature range up to 250 °C.
ISSN:1754-5692
1754-5706
DOI:10.1039/d4ee03705g