Significant Improvements in Dielectric Constant and Energy Density of Ferroelectric Polymer Nanocomposites Enabled by Ultralow Contents of Nanofillers

Li, Li; Cheng, Jingsai; Cheng, Yi; Han, Ting; Liu, Yang; Zhou, Yao; Zhao, Guanghui; Zhao, Yan; Xiong, Chuanxi; Dong, Lijie; Wang, Qing

doi:10.1002/adma.202102392

Cited by 108 publications

(89 citation statements)

References 57 publications

(77 reference statements)

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“…Figure 4d presents a comparison of the U d and η values of our gradient polymer film with those of recently reported high-energy-density polymer-based dielectrics including polymer nanocomposites. [11,[21][22][23]43,50,52,53,[61][62][63][64] The comparison demonstrates the superiority of the energy storage performances achieved with nonlinear gradient polymer films. It is known that ferroelectric PVDF-based polymers usually suffer from a low η (below 80%), limiting their practical application in capacitor applications; [53,65] therefore, concurrently high U d and η are desirable.…”

Section: Resultsmentioning

confidence: 89%

Ultrahigh Energy Density in Continuously Gradient‐Structured All‐Organic Dielectric Polymer Films

Jiang

Wang

Yan

et al. 2022

Adv Funct Materials

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High‐performance dielectric capacitors are critical for advanced electronics and electrical power systems. Polymeric dielectrics have been widely investigated for using in dielectric capacitors because of their high dielectric constants, flexibility, low density, and easy processability. However, it is still challenging to achieve simultaneous improvements in both energy density and efficiency in these dielectric polymers. Here, we report ferroelectric polyvinylidene‐fluoride‐based all‐organic dielectric polymer films with continuous compositional gradient structure are reported by modulating the spatial distribution of polymethyl‐methacrylate components, prepared via a facile and scalable additive manufacturing method. The continuous out‐of‐plane composition gradient in the all‐organic dielectric polymer films allows to tune electrical and mechanical behaviors, and thus induces a notably enhanced breakdown strength by modulating the electromechanical breakdown process related to the coupling of local electric field and stress. An ultrahigh discharge energy density of 38.8 J cm−3 along with a high discharge efficiency of >80% is achieved at the electric field of 800 kV mm−1 in the gradient polymer films, which is the highest energy density reported thus far in polymer‐based dielectrics including their nanocomposites and the highest energy efficiency achieved along with an energy density of >30 J cm−3.

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Section: Resultsmentioning

confidence: 89%

Ultrahigh Energy Density in Continuously Gradient‐Structured All‐Organic Dielectric Polymer Films

Jiang

Wang

Yan

et al. 2022

Adv Funct Materials

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“…Crosslinked PVDF [52] 2.0 wt.% BaTiO 3 -DPA 11.6 (100 Hz) 0.135 (100 Hz) 242 2.9 @ 275 MV/m 75 PVDF [53] 4 vol.% modified BaTiO 3 ~11.5 ~0.02 517 11.27 @ 520 MV/m 60 PVDF [54] 50 vol.% modified BaTiO 3 ~28 0.038 328 9.89 60 P(VDF-HFP) [79] 10 vol.% SiO 2 986.2 27.1 0.03 390 5.1 P(VDF-HFP) [128] 0.82 vol.% CdSe/Cd 1D nanofillers PVDF [51] 2.1 vol.% BaTiO 3 -PDA ~11 <0.04 340.4 7.03 @ 330 MV/m P(VDF-HFP) [58] 5 vol.% BaTiO 3 -PDA ~12 ~0.05 ~470 12.87 @ 480 MV/m ~55 P(VDF-CTFE) [59] 3 vol.% Z-aligned BaTiO 3 ~16 271.9 10.8 @ 240 MV/m 61.4…”

Section: D Nanofillersmentioning

confidence: 99%

Recent progress on dielectric polymers and composites for capacitive energy storage

Han

Wang

2022

iEnergy

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Polymer dielectrics-based capacitors are indispensable to the development of increasingly complex, miniaturized and sustainable electronics and electrical systems. However, the current polymer dielectrics are limited by their relatively low discharged energy density, efficiency and poor high-temperature performance. Here, we review the recent advances in the development of high-performance polymer and composite dielectrics for capacitive energy storage applications at both ambient and elevated temperature (≥ 150 °C). We highlight the underlying rationale behind the material development by constructing the relationship between the physical properties of materials and their energy-storage capability. Challenges and future opportunities are discussed at the end of the review.

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“…Li et al 9 constructed the interface bonding region by modifying the surface of nanofillers and proposed the multi‐regions model. Wang et al 10 established the dielectric model based on the multi‐core model and density functional theory to explore the limitations of the volume average model of low content composites, and so on. In addition to establish the model, researchers also attempted other strategies to explore the mechanisms that the interface enhances the insulation properties.…”

Section: Introductionmentioning

confidence: 99%

Low‐content metal‐organic framework enhanced interface effect to improve the insulation properties of polyimide‐based composite films

Hui

Feng

et al. 2022

Polymers for Advanced Techs

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Polymer‐based nanodielectrics are widely used in microelectronics, aerospace and electrical insulation fields because of their excellent insulation and mechanical properties, but the strategies and mechanisms to improve their insulation strength need to be further studied. Herein, introducing MOFs (UiO‐66) particles into polyimide (PI) matrix obtained the unexpected discovery that MOFs with 3D porous structure did not degrade the insulation strength and mechanical stretching of composite films, conversely, remarkably increased the breakdown strength (Eb) and mechanical strength at low doping concentration. With only 1 wt% doped of UiO‐66, the maximum Eb of UiO‐66/PI composite film is 458.6 kV/mm, which is about 64% higher than PI (279.8 kV/mm). To study the mechanism of performance improvement, the interface structure was characterized by synchrotron radiation small‐angle X‐ray scattering, and the interface influence factor is introduced to modify the classical dielectric model. It was found that the hydroxyl groups on UiO‐66 can form hydrogen bonds with the PI molecular chain, and this strong interaction at the interface is the main reason for the performance improvement of low‐content doped composites. This study provides a strategy for improving the insulation properties of composites at low doping and offers some insights into the application of MOFs in high performance dielectrics.

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Significant Improvements in Dielectric Constant and Energy Density of Ferroelectric Polymer Nanocomposites Enabled by Ultralow Contents of Nanofillers

Cited by 108 publications

References 57 publications

Ultrahigh Energy Density in Continuously Gradient‐Structured All‐Organic Dielectric Polymer Films

Ultrahigh Energy Density in Continuously Gradient‐Structured All‐Organic Dielectric Polymer Films

Recent progress on dielectric polymers and composites for capacitive energy storage

Low‐content metal‐organic framework enhanced interface effect to improve the insulation properties of polyimide‐based composite films

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