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High breakdown strength and outstanding piezoelectric performance in flexible PVDF based percolative nanocomposites through the synergistic effect of topological-structure and composition modulations

High breakdown strength and outstanding piezoelectric performance in flexible PVDF based percolative nanocomposites through the synergistic effect of topological-structure and composition modulations
High breakdown strength and outstanding piezoelectric performance in flexible PVDF based percolative nanocomposites through the synergistic effect of topological-structure and composition modulations
Over decades, the fabrication of flexible poly(vinylidene fluoride) (PVDF) based percolative nanocomposites with high piezoelectric performance is of great concern from both academia and industry. However, the issue of sharply declined breakdown strength in percolative nanocomposites poses an obstacle to realizing the full potential of conductive nanofillers in enhancing piezoelectricity. Herein, we demonstrated that through proper topological structure and composition modulations, notably improved breakdown strength and piezoelectric performance can be achieved in PVDF based percolative nanocomposites. By constructing a sandwiched structure where a layer of high breakdown strength is intercalated between layers containing high content (near percolation threshold) of conductive nanofillers, the breakdown strength of overall nanocomposites is significantly strengthened and thus allows for sufficient poling of outer layers, fulfilling the great potential of conductive nanofillers in yielding piezoelectricity enhancement. A super high piezoelectric coefficient d33 of 48 pC/N is obtained in the optimized sandwich nanocomposites.
A. Nanocomposites, A. Sandwich structures, B. Electrical properties
1359-835X
13-20
Yang, Lu
137d4b84-e283-4d52-be57-b9857c9e0ba1
Zhao, Qiuying
06045aaa-fb4a-4ff4-b659-8ff7938f3ad2
Hou, Ying
e4bf7379-822f-40a6-b6f4-56a13665b989
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Cheng, Meng
58f35da3-a280-4003-8a99-62b9f572c679
Shen, Mingxia
3c6092df-ba5a-44df-a8e7-d8e3a273f7b0
Zeng, Shaohua
212f0c3e-73d6-4a39-b70d-5a849c1abea8
Ji, Hongli
bf30b13a-6237-49ea-a1f6-2e2f9535b10f
Qiu, Jinhao
9b6c6e23-5e3a-42dc-a678-18e020f2c6b5
Yang, Lu
137d4b84-e283-4d52-be57-b9857c9e0ba1
Zhao, Qiuying
06045aaa-fb4a-4ff4-b659-8ff7938f3ad2
Hou, Ying
e4bf7379-822f-40a6-b6f4-56a13665b989
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Cheng, Meng
58f35da3-a280-4003-8a99-62b9f572c679
Shen, Mingxia
3c6092df-ba5a-44df-a8e7-d8e3a273f7b0
Zeng, Shaohua
212f0c3e-73d6-4a39-b70d-5a849c1abea8
Ji, Hongli
bf30b13a-6237-49ea-a1f6-2e2f9535b10f
Qiu, Jinhao
9b6c6e23-5e3a-42dc-a678-18e020f2c6b5

Yang, Lu, Zhao, Qiuying, Hou, Ying, Sun, Rujie, Cheng, Meng, Shen, Mingxia, Zeng, Shaohua, Ji, Hongli and Qiu, Jinhao (2018) High breakdown strength and outstanding piezoelectric performance in flexible PVDF based percolative nanocomposites through the synergistic effect of topological-structure and composition modulations. Composites Part A: Applied Science and Manufacturing, 114, 13-20. (doi:10.1016/j.compositesa.2018.07.039).

Record type: Article

Abstract

Over decades, the fabrication of flexible poly(vinylidene fluoride) (PVDF) based percolative nanocomposites with high piezoelectric performance is of great concern from both academia and industry. However, the issue of sharply declined breakdown strength in percolative nanocomposites poses an obstacle to realizing the full potential of conductive nanofillers in enhancing piezoelectricity. Herein, we demonstrated that through proper topological structure and composition modulations, notably improved breakdown strength and piezoelectric performance can be achieved in PVDF based percolative nanocomposites. By constructing a sandwiched structure where a layer of high breakdown strength is intercalated between layers containing high content (near percolation threshold) of conductive nanofillers, the breakdown strength of overall nanocomposites is significantly strengthened and thus allows for sufficient poling of outer layers, fulfilling the great potential of conductive nanofillers in yielding piezoelectricity enhancement. A super high piezoelectric coefficient d33 of 48 pC/N is obtained in the optimized sandwich nanocomposites.

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More information

Accepted/In Press date: 31 July 2018
e-pub ahead of print date: 1 August 2018
Published date: 15 August 2018
Keywords: A. Nanocomposites, A. Sandwich structures, B. Electrical properties

Identifiers

Local EPrints ID: 486929
URI: http://eprints.soton.ac.uk/id/eprint/486929
ISSN: 1359-835X
PURE UUID: 9f410f07-c23b-4876-948a-f3ee3ca7b9bb

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Date deposited: 08 Feb 2024 17:44
Last modified: 17 Mar 2024 07:24

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Contributors

Author: Lu Yang
Author: Qiuying Zhao
Author: Ying Hou
Author: Rujie Sun
Author: Meng Cheng
Author: Mingxia Shen
Author: Shaohua Zeng
Author: Hongli Ji
Author: Jinhao Qiu

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