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Enhanced energy storage properties of thermostable sandwich-structured BaTiO3/polyimide nanocomposites with better controlled interfaces

Enhanced energy storage properties of thermostable sandwich-structured BaTiO3/polyimide nanocomposites with better controlled interfaces
Enhanced energy storage properties of thermostable sandwich-structured BaTiO3/polyimide nanocomposites with better controlled interfaces
The energy density of polymers for high temperature applications is still relatively low. Among them, polyimide (PI) is one of the most attractive matrixes because of its high thermal stability. Instead of the mono thermal imidization method to fabricate multilayer PI nanocomposites in the literature, a novel method was proposed herein to better control the multilayer morphology, which could help to further enhance the energy storage properties. The method's effect on themorphology especially on the interfaces between adjacent layerswas studied, and then the mechanismof breakdownstrength change was discussed by a proposedmodel based on bipolar charge transport. The sandwich-structured PI nanocomposites, composed of the middle polarization layer with
high BaTiO3 (BT) content and the two outer insulation layers with low BT content, were fabricated. Enhanced breakdown field and discharged energy density of 550 kV/mm and 5.1 J/cm3 with the efficiency of about 70% were achieved, while keeping a high thermal stability (500 kV/mm and 3.9 J/cm3 at 100 °C). This work presents a promising polymer nanocomposite for energy storage capacitors especially in extreme temperature environments, and a new concept to fabricate multilayer dielectric composites.
0261-3069
Ru, Jiasheng
dafeb495-41f6-464e-a725-6aa58f6cfbfb
Min, Daomin
527e3301-88e9-4582-af20-680e1ec36b73
Lanagan, Michael
d93b69a4-e61b-45d7-a300-f8ad04d4d684
Li, Shengtao
ac89cccc-84c3-4d06-b952-503ecde73b2a
Chen, George
3de45a9c-6c9a-4bcb-90c3-d7e26be21819
Ru, Jiasheng
dafeb495-41f6-464e-a725-6aa58f6cfbfb
Min, Daomin
527e3301-88e9-4582-af20-680e1ec36b73
Lanagan, Michael
d93b69a4-e61b-45d7-a300-f8ad04d4d684
Li, Shengtao
ac89cccc-84c3-4d06-b952-503ecde73b2a
Chen, George
3de45a9c-6c9a-4bcb-90c3-d7e26be21819

Ru, Jiasheng, Min, Daomin, Lanagan, Michael, Li, Shengtao and Chen, George (2020) Enhanced energy storage properties of thermostable sandwich-structured BaTiO3/polyimide nanocomposites with better controlled interfaces. Materials and Design, 197. (doi:10.1016/j.matdes.2020.109270).

Record type: Article

Abstract

The energy density of polymers for high temperature applications is still relatively low. Among them, polyimide (PI) is one of the most attractive matrixes because of its high thermal stability. Instead of the mono thermal imidization method to fabricate multilayer PI nanocomposites in the literature, a novel method was proposed herein to better control the multilayer morphology, which could help to further enhance the energy storage properties. The method's effect on themorphology especially on the interfaces between adjacent layerswas studied, and then the mechanismof breakdownstrength change was discussed by a proposedmodel based on bipolar charge transport. The sandwich-structured PI nanocomposites, composed of the middle polarization layer with
high BaTiO3 (BT) content and the two outer insulation layers with low BT content, were fabricated. Enhanced breakdown field and discharged energy density of 550 kV/mm and 5.1 J/cm3 with the efficiency of about 70% were achieved, while keeping a high thermal stability (500 kV/mm and 3.9 J/cm3 at 100 °C). This work presents a promising polymer nanocomposite for energy storage capacitors especially in extreme temperature environments, and a new concept to fabricate multilayer dielectric composites.

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Accepted/In Press date: 25 October 2020
e-pub ahead of print date: 28 October 2020

Identifiers

Local EPrints ID: 473655
URI: http://eprints.soton.ac.uk/id/eprint/473655
ISSN: 0261-3069
PURE UUID: 806c5876-7c88-43bb-affe-50e3c088c9ff

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Date deposited: 26 Jan 2023 17:50
Last modified: 16 Mar 2024 23:46

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Contributors

Author: Jiasheng Ru
Author: Daomin Min
Author: Michael Lanagan
Author: Shengtao Li
Author: George Chen

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