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Enhanced energy storage performance of nano-submicron structural dielectric films by suppressed ferroelectric phase aggregation
by
Hao, Yanan
, Liang, Tong
, Huang, Lei
, Gao, Yi
, Meng, Yan
, Wang, Xin-Jie
, Xing, Kun
, Dang, Zhi-Min
, Bi, Ke
, Zhong, Shao-Long
in
147/135
/ 147/143
/ 639/766/119
/ 639/766/119/996
/ Breakdown
/ Charge efficiency
/ Design
/ Dielectrics
/ Discharge
/ Efficiency
/ Electric fields
/ Energy charge
/ Energy storage
/ Ferroelectric materials
/ Ferroelectricity
/ Fluorides
/ Humanities and Social Sciences
/ multidisciplinary
/ Polymers
/ Polymethyl methacrylate
/ Science
/ Science (multidisciplinary)
/ Surface layers
2025
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Enhanced energy storage performance of nano-submicron structural dielectric films by suppressed ferroelectric phase aggregation
by
Hao, Yanan
, Liang, Tong
, Huang, Lei
, Gao, Yi
, Meng, Yan
, Wang, Xin-Jie
, Xing, Kun
, Dang, Zhi-Min
, Bi, Ke
, Zhong, Shao-Long
in
147/135
/ 147/143
/ 639/766/119
/ 639/766/119/996
/ Breakdown
/ Charge efficiency
/ Design
/ Dielectrics
/ Discharge
/ Efficiency
/ Electric fields
/ Energy charge
/ Energy storage
/ Ferroelectric materials
/ Ferroelectricity
/ Fluorides
/ Humanities and Social Sciences
/ multidisciplinary
/ Polymers
/ Polymethyl methacrylate
/ Science
/ Science (multidisciplinary)
/ Surface layers
2025
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While trying to remove the title from your shelf something went wrong :( Kindly try again later!
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Enhanced energy storage performance of nano-submicron structural dielectric films by suppressed ferroelectric phase aggregation
by
Hao, Yanan
, Liang, Tong
, Huang, Lei
, Gao, Yi
, Meng, Yan
, Wang, Xin-Jie
, Xing, Kun
, Dang, Zhi-Min
, Bi, Ke
, Zhong, Shao-Long
in
147/135
/ 147/143
/ 639/766/119
/ 639/766/119/996
/ Breakdown
/ Charge efficiency
/ Design
/ Dielectrics
/ Discharge
/ Efficiency
/ Electric fields
/ Energy charge
/ Energy storage
/ Ferroelectric materials
/ Ferroelectricity
/ Fluorides
/ Humanities and Social Sciences
/ multidisciplinary
/ Polymers
/ Polymethyl methacrylate
/ Science
/ Science (multidisciplinary)
/ Surface layers
2025
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Enhanced energy storage performance of nano-submicron structural dielectric films by suppressed ferroelectric phase aggregation
Journal Article
Enhanced energy storage performance of nano-submicron structural dielectric films by suppressed ferroelectric phase aggregation
2025
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Overview
Maintaining high charge/discharge efficiency while enhancing discharged energy density is crucial for energy storage dielectric films applied in electrostatic capacitors. Here, a nano-submicron structural film comprising ferroelectric material P(VDF-HFP) and linear dielectric material PMMA has been flexibly designed via the electrospinning process. Nano-submicron structure enables the film to maximize the ferroelectric material component and obtain improved dielectric performance without sacrificing breakdown strength and charge/discharge efficiency. As a result, the 40%-420 nm PMMA-P(VDF-HFP)@PMMA sample achieved an discharged energy density of 13.72 J/cm³ at a field of 740 kV/mm, with an impressive charge/discharge efficiency of 80%. This work presents a composite dielectric film that excels in breakdown strength, discharged energy density, and charge/discharge efficiency, offering a strategy for designing reliable, industrial-grade energy storage dielectrics.
The authors prepare an all-organic dielectric film with a nano-submicron surface layer via electrospinning technology, achieving a simultaneous improvement in the discharged energy density and charge/discharge efficiency.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
Subject
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