Ultrahigh energy density in dielectric nanocomposites by modulating nanofiller orientation and polymer crystallization behavior

Ru Guo, Hang Luo, Di Zhai, Zhida Xiao, Haoran Xie, Yuan Liu, Fan Wang, Xun Jiang, Dou Zhang
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Abstract

High-energy density dielectrics for electrostatic capacitors are in urgent demand for advanced electronics and electrical power systems. Poly(vinylidene fluoride) (PVDF) based nanocomposites have attracted remarkable attention by intrinsic high polarization, flexibility, low density, and outstanding processability. However, it is still challenging to achieve significant improvement in energy density due to the common contradictions between electric polarization and breakdown strength. Here, we proposed a novel facile strategy that simultaneously achieves the construction of in-plane oriented BaTiO3 nanowires and crystallization modulation of PVDF matrix via an in-situ uniaxial stretch process. The polar phase transition and enhanced Young's modulus facilitate the synergetic improvement of electric polarization and voltage endurance capability for PVDF matrix. Additionally, the aligned distribution of nanowires could reduce the contact probability of nanowire tips, thus alleviating electric field concentration and hindering the conductive path. Finally, a record high energy density of 38.3 ​J/cm3 and 40.9 ​J/cm3 are achieved for single layer and optimized sandwich-structured nanocomposite, respectively. This work provides a unique structural design and universal method for dielectric nanocomposites with ultrahigh energy density, which presents a promising prospect of practical application for modern energy storage systems.

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通过调节纳米填料取向和聚合物结晶行为实现介电纳米复合材料的超高能量密度
先进电子和电力系统急需用于静电电容器的高能量密度电介质。基于聚偏二氟乙烯(PVDF)的纳米复合材料因其固有的高极化性、柔韧性、低密度和出色的可加工性而备受关注。然而,由于电极化和击穿强度之间的常见矛盾,要实现能量密度的显著提高仍具有挑战性。在此,我们提出了一种新颖而简便的策略,通过原位单轴拉伸工艺同时实现了面内取向 BaTiO3 纳米线的构建和 PVDF 基体的结晶调制。极性相变和增强的杨氏模量促进了 PVDF 基体电极化和耐电压能力的协同改善。此外,纳米线的排列分布可以降低纳米线尖端的接触概率,从而减轻电场集中和阻碍导电路径。最后,单层和优化夹层结构纳米复合材料的能量密度分别达到了创纪录的 38.3 J/cm3 和 40.9 J/cm3。这项工作为具有超高能量密度的介电纳米复合材料提供了独特的结构设计和通用方法,为现代储能系统的实际应用带来了广阔前景。
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