考虑电荷捕获效应模拟聚酰亚胺纳米复合材料的高温储能和释放性能

IF 3.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Poxin Wang, Daomin Min, Xiaofan Song, Ziwei Gao, Yutao Hao, Shihang Wang, Wenfeng Liu
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引用次数: 0

摘要

具有优异耐高温性能的介质储能电容器在航空航天、脉冲电源等领域是必不可少的。然而,常见的耐高温聚合物如聚酰亚胺(PI)和聚醚砜在高温下具有较低的储能密度和能量效率,这在实际应用中受到很大限制。通过掺杂改性制备的聚合物纳米复合材料可以调节电荷注入和输运过程,提高高温储能性能。然而,电荷注入和电荷俘获与线性聚合物纳米复合材料储能性能之间的定量关系仍需进一步研究。建立了考虑电荷俘获效应的能量存储与释放模型。我们模拟了具有不同电荷注入势垒和陷阱参数的聚酰亚胺纳米复合电介质(PI pnc)在150°C下的高温储能性能。在PI pnc两侧的电极上施加三角形电压,模拟了电场-位移回路,计算了放电能量密度和能量效率。仿真结果与实验结果吻合较好。增加电荷注入势垒、深阱能量和深阱密度可以有效地降低电荷注入和载流子迁移率,从而提高介质电容器的放电能量密度和能量效率。在低电荷注入势垒(1.3 eV)条件下,随着深阱能量(0.7 ~ 1.5 eV)和深阱密度(1 × 1021 ~ 1 × 1025 m−3)的增加,放电能量密度从0.20 Jcm−3增加到1.44 Jcm−3,能量效率从9.0%增加到99.9%,高温储能性能显著提高。该研究为提高纳米复合材料的高温储能性能提供了理论和模型支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

High temperature energy storage and release properties of polyimide nanocomposites simulated by considering charge trapping effects

High temperature energy storage and release properties of polyimide nanocomposites simulated by considering charge trapping effects

Dielectric energy storage capacitors with excellent high temperature resistance are essential in fields such as aerospace and pulse power. However, common high-temperature resistant polymers such as polyimide (PI) and polyether sulfone have low energy storage densities and energy efficiencies at high temperature, which are greatly limited in practical applications. The polymer nanocomposites prepared by doping modification can regulate the charge injection and transport process, and improve the high-temperature energy storage performance. However, the quantitative relationship between charge injection and charge trapping and the energy storage performance of linear polymer nanocomposites still needs further study. An energy storage and release model considering the charge trapping effects is constructed by the authors. We simulate the high-temperature energy storage properties of polyimide nanocomposite dielectrics (PI PNCs) with different charge injection barriers and trap parameters at 150°C. A triangular voltage is applied to the electrodes at both sides of the PI PNCs, the electric displacement-electric field loop is simulated, and the discharged energy densities and energy efficiencies are calculated. The simulation results are consistent with the experimental results. Increasing the charge injection barrier, deep trap energy and deep trap density can effectively reduce the charge injection and the carrier mobility, thereby improving the discharged energy densities and energy efficiencies of dielectric capacitors. In the case of low charge injection barrier (1.3 eV), with the increase of deep trap energy (0.7–1.5 eV) and deep trap density (1 × 1021–1 × 1025 m−3), the discharged energy density changes from 0.20 to 1.44 Jcm−3, the energy efficiency changes from 9.0% to 99.9%, and the high-temperature energy storage performance improves significantly. This research provides theoretical and model support for the improvement of the high-temperature energy storage performance of nanocomposites.

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来源期刊
IET Nanodielectrics
IET Nanodielectrics Materials Science-Materials Chemistry
CiteScore
5.60
自引率
3.70%
发文量
7
审稿时长
21 weeks
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