Modulating the charge trapping characteristics of PEI/BNNPs dilute nanocomposite for improved high-temperature energy storage performance†

IF 5.7 2区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Materials Chemistry C Pub Date : 2022-08-22 DOI:10.1039/D2TC02462D
Jingjing Yan, Jian Wang, Junyang Zeng, Zhonghui Shen, Baowen Li, Xin Zhang and Shujun Zhang
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引用次数: 10

Abstract

Flexible polymeric dielectrics with excellent energy density and high temperature resistance are essential in modern electronic communication and industrial systems. However, current polymeric dielectrics suffer from seriously deteriorated energy density with the increase of temperature, which is caused by the exceptionally increased leakage current under high voltage and high temperature. Here, based on the results of thermally stimulated depolarization current measurements and phase-filed simulations, we demonstrate that an ultralow (0.25–0.75%) volume fraction of high-insulative boron nitride nanoparticles (BNNPs) can generate deep traps and shorten the hopping distance for mobile charges in a polyetherimide (PEI) nanocomposite, thereby suppressing conduction loss and improving breakdown strength at 150 °C. In addition, it's found that the dielectric constant of the nanocomposites is remarkably enhanced at ultra-low loading of BNNPs compared to the pristine PEI. Accordingly, with the simultaneous enhancement of the dielectric constant and breakdown field strength, the PEI-based dilute nanocomposite film yields a high energy density of 4.2 J cm?3 and the ultrahigh charge–discharge efficiency of 90% at 150 °C. This work offers a facile and scalable approach to adjusting the charge transport and trapping behaviors of polymeric dielectrics for improved high temperature electrostatic energy storage performance, which is of significant importance for their practical applications in high-temperature electrical and electronic systems.

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调节PEI/BNNPs稀纳米复合材料的电荷俘获特性以提高高温储能性能
柔性聚合物电介质具有优异的能量密度和耐高温性能,是现代电子通信和工业系统中必不可少的材料。然而,随着温度的升高,电流聚合物介质的能量密度严重恶化,这是由于高压和高温下泄漏电流异常增大造成的。在此,基于热刺激退极化电流测量和相场模拟的结果,我们证明了超低(0.25-0.75%)体积分数的高绝缘氮化硼纳米颗粒(BNNPs)可以在聚醚酰亚胺(PEI)纳米复合材料中产生深阱并缩短移动电荷的跳跃距离,从而抑制传导损失并提高150°C下的击穿强度。此外,与原始PEI相比,超低负载BNNPs的纳米复合材料的介电常数显著提高。因此,随着介电常数和击穿场强的同时增强,pei基稀纳米复合膜的能量密度高达4.2 J cm?3、150℃时高达90%的超高充放电效率。本研究提供了一种简便、可扩展的方法来调整聚合物电介质的电荷传输和捕获行为,以改善高温静电储能性能,这对聚合物电介质在高温电气和电子系统中的实际应用具有重要意义。
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来源期刊
Journal of Materials Chemistry C
Journal of Materials Chemistry C MATERIALS SCIENCE, MULTIDISCIPLINARY-PHYSICS, APPLIED
CiteScore
10.80
自引率
6.20%
发文量
1468
期刊介绍: The Journal of Materials Chemistry is divided into three distinct sections, A, B, and C, each catering to specific applications of the materials under study: Journal of Materials Chemistry A focuses primarily on materials intended for applications in energy and sustainability. Journal of Materials Chemistry B specializes in materials designed for applications in biology and medicine. Journal of Materials Chemistry C is dedicated to materials suitable for applications in optical, magnetic, and electronic devices. Example topic areas within the scope of Journal of Materials Chemistry C are listed below. This list is neither exhaustive nor exclusive. Bioelectronics Conductors Detectors Dielectrics Displays Ferroelectrics Lasers LEDs Lighting Liquid crystals Memory Metamaterials Multiferroics Photonics Photovoltaics Semiconductors Sensors Single molecule conductors Spintronics Superconductors Thermoelectrics Topological insulators Transistors
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