High energy density of polyimide films employing an imidization reaction kinetics strategy at elevated temperature
High energy density of polyimide films employing an imidization reaction kinetics strategy at elevated temperature
Polymer dielectrics have been widely used in electrical energy storage devices. However, the relatively low operating temperature hinders their applications in harsh environments. Herein, the molecular structure of polyimide (PI) is optimized by adjusting the reaction kinetics of polyamic acid, which improves the energy storage performance of PI at elevated temperature. The PI film with an optimal imidization degree achieves a simultaneous increase in dielectric permittivity (ϵ r) and breakdown strength (E b), resulting in a maximum discharged energy density (U e) of 6.9 J cm −3 with a charge-discharge efficiency of 90.0% at room temperature and a high U e of 3.9 J cm −3 at 150 °C. The introduced -COOH/-CN-OH- polar groups increase the ϵ r through the enhancement of dipole polarization. Moreover, an appropriate number of -COOH/-CN-OH- groups as deep traps reduce the mobility of carriers, thereby increasing the E b. Finite element simulation reveals that PI with an appropriate imidization degree exhibits suppressed space charge accumulation and improved electric field distortion. This method reduces the PI processing temperature, which effectively reduces the production energy consumption. For verifying the universality of the design strategy, two other PIs prepared from different monomers are also demonstrated to have simultaneous improvement in ϵ r and E b.Finally, this production process of only reducing the preparation temperature without adjusting the original commercial PI production equipment is crucial for the practical application of capacitor films in the future.
10950 - 10959
Liu, Xue-Jie
6cda03cd-8978-4f6d-8f0c-6bbe0f16a5b3
Zheng, Ming-Sheng
9c2ee64b-0fe7-4350-aa7c-b15be4990dfb
Wang, Gang
13ad4d8d-a175-425e-8155-6ec1790b6aee
Zhang, Yi-Yi
21f65196-cfd6-475b-aa46-888cd47a241d
Dang, Zhi-Min
4b41a602-16db-4db0-bf98-1ebd9870b16f
Chen, George
3de45a9c-6c9a-4bcb-90c3-d7e26be21819
Zha, Jun-Wei
d66e2b58-d1d5-4d37-a421-f892078a72fa
11 April 2022
Liu, Xue-Jie
6cda03cd-8978-4f6d-8f0c-6bbe0f16a5b3
Zheng, Ming-Sheng
9c2ee64b-0fe7-4350-aa7c-b15be4990dfb
Wang, Gang
13ad4d8d-a175-425e-8155-6ec1790b6aee
Zhang, Yi-Yi
21f65196-cfd6-475b-aa46-888cd47a241d
Dang, Zhi-Min
4b41a602-16db-4db0-bf98-1ebd9870b16f
Chen, George
3de45a9c-6c9a-4bcb-90c3-d7e26be21819
Zha, Jun-Wei
d66e2b58-d1d5-4d37-a421-f892078a72fa
Liu, Xue-Jie, Zheng, Ming-Sheng, Wang, Gang, Zhang, Yi-Yi, Dang, Zhi-Min, Chen, George and Zha, Jun-Wei
(2022)
High energy density of polyimide films employing an imidization reaction kinetics strategy at elevated temperature.
Journal of Materials Chemistry A, 20 (10), .
(doi:10.1039/d2ta01226j).
Abstract
Polymer dielectrics have been widely used in electrical energy storage devices. However, the relatively low operating temperature hinders their applications in harsh environments. Herein, the molecular structure of polyimide (PI) is optimized by adjusting the reaction kinetics of polyamic acid, which improves the energy storage performance of PI at elevated temperature. The PI film with an optimal imidization degree achieves a simultaneous increase in dielectric permittivity (ϵ r) and breakdown strength (E b), resulting in a maximum discharged energy density (U e) of 6.9 J cm −3 with a charge-discharge efficiency of 90.0% at room temperature and a high U e of 3.9 J cm −3 at 150 °C. The introduced -COOH/-CN-OH- polar groups increase the ϵ r through the enhancement of dipole polarization. Moreover, an appropriate number of -COOH/-CN-OH- groups as deep traps reduce the mobility of carriers, thereby increasing the E b. Finite element simulation reveals that PI with an appropriate imidization degree exhibits suppressed space charge accumulation and improved electric field distortion. This method reduces the PI processing temperature, which effectively reduces the production energy consumption. For verifying the universality of the design strategy, two other PIs prepared from different monomers are also demonstrated to have simultaneous improvement in ϵ r and E b.Finally, this production process of only reducing the preparation temperature without adjusting the original commercial PI production equipment is crucial for the practical application of capacitor films in the future.
Text
final submitted manuscript
- Accepted Manuscript
Text
d2ta01226j
- Version of Record
Restricted to Repository staff only
Request a copy
More information
Accepted/In Press date: 11 April 2022
Published date: 11 April 2022
Additional Information:
Funding Information:
This work was financially supported by the National Natural Science Foundation of China (No. 51977114), Fundamental Research Funds for the Central Universities (No. FRF-NP-19-008 and FRF-TP-20-02B2), and Scientific and Technological Innovation Foundation of Foshan (BK21BE006). The authors appreciate the help offered by Prof. Meng Xiao from Tianjin University for the isothermal surface potential decay tests. The authors thank Hang-Dong Li from Guangxi University for his kind help.
Publisher Copyright:
© 2022 The Royal Society of Chemistry
Identifiers
Local EPrints ID: 469993
URI: http://eprints.soton.ac.uk/id/eprint/469993
ISSN: 2050-7488
PURE UUID: 9d5ef653-e964-4e1f-935f-f510983f1733
Catalogue record
Date deposited: 29 Sep 2022 16:53
Last modified: 17 Mar 2024 07:30
Export record
Altmetrics
Contributors
Author:
Xue-Jie Liu
Author:
Ming-Sheng Zheng
Author:
Gang Wang
Author:
Yi-Yi Zhang
Author:
Zhi-Min Dang
Author:
George Chen
Author:
Jun-Wei Zha
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics